mirrors
/
Tasmota
mirror of https://github.com/arendst/Tasmota.git
1
0
Fork 0
Code Issues Packages Projects Releases Wiki Activity
Tasmota/sonoff/xsns_hlw8012.ino

636 lines
20 KiB
C++
Raw Blame History

/*
Copyright (c) 2017 Theo Arends. All rights reserved.
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are met:
- Redistributions of source code must retain the above copyright notice,
this list of conditions and the following disclaimer.
- Redistributions in binary form must reproduce the above copyright notice,
this list of conditions and the following disclaimer in the documentation
and/or other materials provided with the distribution.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
POSSIBILITY OF SUCH DAMAGE.
*/
/*********************************************************************************************\
* HLW8012 - Energy
*
* Based on Source: Shenzhen Heli Technology Co., Ltd
\*********************************************************************************************/
#define FEATURE_POWER_LIMIT true
/*********************************************************************************************/
#define HLW_PREF 10000 // 1000.0W
#define HLW_UREF 2200 // 220.0V
#define HLW_IREF 4545 // 4.545A
byte hlw_pminflg = 0;
byte hlw_pmaxflg = 0;
byte hlw_uminflg = 0;
byte hlw_umaxflg = 0;
byte hlw_iminflg = 0;
byte hlw_imaxflg = 0;
byte power_steady_cntr;
byte hlw_mkwh_state = 0;
#if FEATURE_POWER_LIMIT
byte hlw_mplr_counter = 0;
uint16_t hlw_mplh_counter = 0;
uint16_t hlw_mplw_counter = 0;
#endif // FEATURE_POWER_LIMIT
byte hlw_SELflag;
byte hlw_cf_timer;
byte hlw_cf1_timer;
byte hlw_fifth_second;
byte hlw_startup;
unsigned long hlw_cf_plen;
unsigned long hlw_cf_last;
unsigned long hlw_cf1_plen;
unsigned long hlw_cf1_last;
unsigned long hlw_cf1_ptot;
unsigned long hlw_cf1_pcnt;
unsigned long hlw_cf1u_plen;
unsigned long hlw_cf1i_plen;
unsigned long hlw_Ecntr;
unsigned long hlw_EDcntr;
unsigned long hlw_kWhtoday;
uint32_t hlw_lasttime;
unsigned long hlw_cf1u_pcntmax;
unsigned long hlw_cf1i_pcntmax;
Ticker tickerHLW;
#ifndef USE_WS2812_DMA // Collides with Neopixelbus but solves exception
void hlw_cf_interrupt() ICACHE_RAM_ATTR;
void hlw_cf1_interrupt() ICACHE_RAM_ATTR;
#endif // USE_WS2812_DMA
void hlw_cf_interrupt() // Service Power
{
hlw_cf_plen = micros() - hlw_cf_last;
hlw_cf_last = micros();
if (hlw_cf_plen > 4000000) {
hlw_cf_plen = 0; // Just powered on
}
hlw_cf_timer = 15; // Support down to 4W which takes about 3 seconds
hlw_EDcntr++;
hlw_Ecntr++;
}
void hlw_cf1_interrupt() // Service Voltage and Current
{
hlw_cf1_plen = micros() - hlw_cf1_last;
hlw_cf1_last = micros();
if ((hlw_cf1_timer > 2) && (hlw_cf1_timer < 8)) { // Allow for 300 mSec set-up time and measure for up to 1 second
hlw_cf1_ptot += hlw_cf1_plen;
hlw_cf1_pcnt++;
if (10 == hlw_cf1_pcnt) {
hlw_cf1_timer = 8; // We need up to ten samples within 1 second (low current could take up to 0.3 second)
}
}
}
void hlw_200mS()
{
unsigned long hlw_len;
unsigned long hlw_temp;
hlw_fifth_second++;
if (5 == hlw_fifth_second) {
hlw_fifth_second = 0;
if (hlw_EDcntr) {
hlw_len = 1000000 / hlw_EDcntr;
hlw_EDcntr = 0;
hlw_temp = (HLW_PREF * sysCfg.hlw_pcal) / hlw_len;
hlw_kWhtoday += (hlw_temp * 100) / 36;
rtcMem.hlw_kWhtoday = hlw_kWhtoday;
}
if (rtcTime.Valid) {
if (rtc_loctime() == rtc_midnight()) {
sysCfg.hlw_kWhyesterday = hlw_kWhtoday;
hlw_kWhtoday = 0;
rtcMem.hlw_kWhtoday = hlw_kWhtoday;
hlw_mkwh_state = 3;
}
if ((rtcTime.Hour == sysCfg.hlw_mkwhs) && (3 == hlw_mkwh_state)) {
hlw_mkwh_state = 0;
}
if (hlw_startup && (rtcTime.DayOfYear == sysCfg.hlw_kWhdoy)) {
hlw_kWhtoday = sysCfg.hlw_kWhtoday;
rtcMem.hlw_kWhtoday = hlw_kWhtoday;
hlw_startup = 0;
}
}
}
if (hlw_cf_timer) {
hlw_cf_timer--;
if (!hlw_cf_timer) {
hlw_cf_plen = 0; // No load for over three seconds
}
}
hlw_cf1_timer++;
if (hlw_cf1_timer >= 8) {
hlw_cf1_timer = 0;
hlw_SELflag = (hlw_SELflag) ? 0 : 1;
digitalWrite(pin[GPIO_HLW_SEL], hlw_SELflag);
if (hlw_cf1_pcnt) {
hlw_cf1_plen = hlw_cf1_ptot / hlw_cf1_pcnt;
} else {
hlw_cf1_plen = 0;
}
if (hlw_SELflag) {
hlw_cf1u_plen = hlw_cf1_plen;
hlw_cf1u_pcntmax = hlw_cf1_pcnt;
} else {
hlw_cf1i_plen = hlw_cf1_plen;
hlw_cf1i_pcntmax = hlw_cf1_pcnt;
}
hlw_cf1_ptot = 0;
hlw_cf1_pcnt = 0;
}
}
void hlw_savestate()
{
sysCfg.hlw_kWhdoy = (rtcTime.Valid) ? rtcTime.DayOfYear : 0;
sysCfg.hlw_kWhtoday = hlw_kWhtoday;
}
boolean hlw_readEnergy(byte option, float &ed, uint16_t &e, uint16_t &w, uint16_t &u, float &i, float &c)
{
unsigned long hlw_len;
unsigned long hlw_temp;
unsigned long hlw_w;
unsigned long hlw_u;
unsigned long hlw_i;
int hlw_period;
int hlw_interval;
//char log[LOGSZ];
//snprintf_P(log, sizeof(log), PSTR("HLW: CF %d, CF1U %d (%d), CF1I %d (%d)"), hlw_cf_plen, hlw_cf1u_plen, hlw_cf1u_pcntmax, hlw_cf1i_plen, hlw_cf1i_pcntmax);
//addLog(LOG_LEVEL_DEBUG, log);
if (hlw_kWhtoday) {
ed = (float)hlw_kWhtoday / 100000000;
} else {
ed = 0;
}
if (option) {
if (!hlw_lasttime) {
hlw_period = sysCfg.tele_period;
} else {
hlw_period = rtc_loctime() - hlw_lasttime;
}
hlw_lasttime = rtc_loctime();
hlw_interval = 3600 / hlw_period;
if (hlw_Ecntr) {
hlw_len = hlw_period * 1000000 / hlw_Ecntr;
hlw_Ecntr = 0;
hlw_temp = ((HLW_PREF * sysCfg.hlw_pcal) / hlw_len) / hlw_interval;
e = hlw_temp / 10;
} else {
e = 0;
}
}
if (hlw_cf_plen) {
hlw_w = (HLW_PREF * sysCfg.hlw_pcal) / hlw_cf_plen;
w = hlw_w / 10;
} else {
w = 0;
}
if (hlw_cf1u_plen && (w || (power &1))) {
hlw_u = (HLW_UREF * sysCfg.hlw_ucal) / hlw_cf1u_plen;
u = hlw_u / 10;
} else {
u = 0;
}
if (hlw_cf1i_plen && w) {
hlw_i = (HLW_IREF * sysCfg.hlw_ical) / hlw_cf1i_plen;
i = (float)hlw_i / 1000;
} else {
i = 0;
}
if (hlw_i && hlw_u && hlw_w && w) {
hlw_temp = (hlw_w * 100) / ((hlw_u * hlw_i) / 1000);
if (hlw_temp > 100) {
hlw_temp = 100;
}
c = (float)hlw_temp / 100;
} else {
c = 0;
}
return true;
}
void hlw_init()
{
if (!sysCfg.hlw_pcal || (4975 == sysCfg.hlw_pcal)) {
sysCfg.hlw_pcal = HLW_PREF_PULSE;
sysCfg.hlw_ucal = HLW_UREF_PULSE;
sysCfg.hlw_ical = HLW_IREF_PULSE;
}
hlw_cf_plen = 0;
hlw_cf_last = 0;
hlw_cf1_plen = 0;
hlw_cf1_last = 0;
hlw_cf1u_plen = 0;
hlw_cf1i_plen = 0;
hlw_cf1u_pcntmax = 0;
hlw_cf1i_pcntmax = 0;
hlw_Ecntr = 0;
hlw_EDcntr = 0;
hlw_kWhtoday = (RTC_Valid()) ? rtcMem.hlw_kWhtoday : 0;
hlw_SELflag = 0; // Voltage;
pinMode(pin[GPIO_HLW_SEL], OUTPUT);
digitalWrite(pin[GPIO_HLW_SEL], hlw_SELflag);
pinMode(pin[GPIO_HLW_CF1], INPUT_PULLUP);
attachInterrupt(pin[GPIO_HLW_CF1], hlw_cf1_interrupt, FALLING);
pinMode(pin[GPIO_HLW_CF], INPUT_PULLUP);
attachInterrupt(pin[GPIO_HLW_CF], hlw_cf_interrupt, FALLING);
hlw_startup = 1;
hlw_lasttime = 0;
hlw_fifth_second = 0;
hlw_cf_timer = 0;
hlw_cf1_timer = 0;
tickerHLW.attach_ms(200, hlw_200mS);
}
/********************************************************************************************/
boolean hlw_margin(byte type, uint16_t margin, uint16_t value, byte &flag, byte &saveflag)
{
byte change;
if (!margin) {
return false;
}
change = saveflag;
if (type) {
flag = (value > margin);
} else {
flag = (value < margin);
}
saveflag = flag;
return (change != saveflag);
}
void hlw_setPowerSteadyCounter(byte value)
{
power_steady_cntr = 2;
}
void hlw_margin_chk()
{
char log[LOGSZ];
char svalue[200]; // was MESSZ
float ped;
float pi;
float pc;
uint16_t uped;
uint16_t piv;
uint16_t pe;
uint16_t pw;
uint16_t pu;
boolean flag;
boolean jsonflg;
if (power_steady_cntr) {
power_steady_cntr--;
return;
}
hlw_readEnergy(0, ped, pe, pw, pu, pi, pc);
if (power && (sysCfg.hlw_pmin || sysCfg.hlw_pmax || sysCfg.hlw_umin || sysCfg.hlw_umax || sysCfg.hlw_imin || sysCfg.hlw_imax)) {
piv = (uint16_t)(pi * 1000);
// snprintf_P(log, sizeof(log), PSTR("HLW: W %d, U %d, I %d"), pw, pu, piv);
// addLog(LOG_LEVEL_DEBUG, log);
snprintf_P(svalue, sizeof(svalue), PSTR("{"));
jsonflg = 0;
if (hlw_margin(0, sysCfg.hlw_pmin, pw, flag, hlw_pminflg)) {
snprintf_P(svalue, sizeof(svalue), PSTR("%s%s\"PowerLow\":\"%s\""), svalue, (jsonflg)?", ":"", getStateText(flag));
jsonflg = 1;
}
if (hlw_margin(1, sysCfg.hlw_pmax, pw, flag, hlw_pmaxflg)) {
snprintf_P(svalue, sizeof(svalue), PSTR("%s%s\"PowerHigh\":\"%s\""), svalue, (jsonflg)?", ":"", getStateText(flag));
jsonflg = 1;
}
if (hlw_margin(0, sysCfg.hlw_umin, pu, flag, hlw_uminflg)) {
snprintf_P(svalue, sizeof(svalue), PSTR("%s%s\"VoltageLow\":\"%s\""), svalue, (jsonflg)?", ":"", getStateText(flag));
jsonflg = 1;
}
if (hlw_margin(1, sysCfg.hlw_umax, pw, flag, hlw_umaxflg)) {
snprintf_P(svalue, sizeof(svalue), PSTR("%s%s\"VoltageHigh\":\"%s\""), svalue, (jsonflg)?", ":"", getStateText(flag));
jsonflg = 1;
}
if (hlw_margin(0, sysCfg.hlw_imin, piv, flag, hlw_iminflg)) {
snprintf_P(svalue, sizeof(svalue), PSTR("%s%s\"CurrentLow\":\"%s\""), svalue, (jsonflg)?", ":"", getStateText(flag));
jsonflg = 1;
}
if (hlw_margin(1, sysCfg.hlw_imax, piv, flag, hlw_imaxflg)) {
snprintf_P(svalue, sizeof(svalue), PSTR("%s%s\"CurrentHigh\":\"%s\""), svalue, (jsonflg)?", ":"", getStateText(flag));
jsonflg = 1;
}
if (jsonflg) {
snprintf_P(svalue, sizeof(svalue), PSTR("%s}"), svalue);
mqtt_publish_topic_P(1, PSTR("MARGINS"), svalue);
}
}
#if FEATURE_POWER_LIMIT
// Max Power
if (sysCfg.hlw_mpl) {
if (pw > sysCfg.hlw_mpl) {
if (!hlw_mplh_counter) {
hlw_mplh_counter = sysCfg.hlw_mplh;
} else {
hlw_mplh_counter--;
if (!hlw_mplh_counter) {
snprintf_P(svalue, sizeof(svalue), PSTR("{\"MaxPowerReached\":\"%d%s\"}"), pw, (sysCfg.value_units) ? " W" : "");
mqtt_publish_topic_P(0, PSTR("WARNING"), svalue);
do_cmnd_power(1, 0);
if (!hlw_mplr_counter) {
hlw_mplr_counter = MAX_POWER_RETRY +1;
}
hlw_mplw_counter = sysCfg.hlw_mplw;
}
}
}
else if (power && (pw <= sysCfg.hlw_mpl)) {
hlw_mplh_counter = 0;
hlw_mplr_counter = 0;
hlw_mplw_counter = 0;
}
if (!power) {
if (hlw_mplw_counter) {
hlw_mplw_counter--;
} else {
if (hlw_mplr_counter) {
hlw_mplr_counter--;
if (hlw_mplr_counter) {
snprintf_P(svalue, sizeof(svalue), PSTR("{\"PowerMonitor\":\"%s\"}"), getStateText(1));
mqtt_publish_topic_P(4, PSTR("POWERMONITOR"), svalue);
do_cmnd_power(1, 1);
} else {
snprintf_P(svalue, sizeof(svalue), PSTR("{\"MaxPowerReachedRetry\":\"%s\"}"), getStateText(0));
mqtt_publish_topic_P(0, PSTR("WARNING"), svalue);
}
}
}
}
}
// Max Energy
if (sysCfg.hlw_mkwh) {
uped = (uint16_t)(ped * 1000);
if (!hlw_mkwh_state && (rtcTime.Hour == sysCfg.hlw_mkwhs)) {
hlw_mkwh_state = 1;
snprintf_P(svalue, sizeof(svalue), PSTR("{\"EnergyMonitor\":\"%s\"}"), getStateText(1));
mqtt_publish_topic_P(4, PSTR("ENERGYMONITOR"), svalue);
do_cmnd_power(1, 1);
}
else if ((1 == hlw_mkwh_state) && (uped >= sysCfg.hlw_mkwh)) {
hlw_mkwh_state = 2;
dtostrf(ped, 1, 3, svalue);
snprintf_P(svalue, sizeof(svalue), PSTR("{\"MaxEnergyReached\":\"%s%s\"}"), svalue, (sysCfg.value_units) ? " kWh" : "");
mqtt_publish_topic_P(0, PSTR("WARNING"), svalue);
do_cmnd_power(1, 0);
}
}
#endif // FEATURE_POWER_LIMIT
}
/*********************************************************************************************\
* Commands
\*********************************************************************************************/
boolean hlw_command(char *type, uint16_t index, char *dataBuf, uint16_t data_len, int16_t payload, char *svalue, uint16_t ssvalue)
{
boolean serviced = true;
if (!strcmp(type,"POWERLOW")) {
if ((data_len > 0) && (payload >= 0) && (payload < 3601)) {
sysCfg.hlw_pmin = payload;
}
snprintf_P(svalue, ssvalue, PSTR("{\"PowerLow\":\"%d%s\"}"), sysCfg.hlw_pmin, (sysCfg.value_units) ? " W" : "");
}
else if (!strcmp(type,"POWERHIGH")) {
if ((data_len > 0) && (payload >= 0) && (payload < 3601)) {
sysCfg.hlw_pmax = payload;
}
snprintf_P(svalue, ssvalue, PSTR("{\"PowerHigh\":\"%d%s\"}"), sysCfg.hlw_pmax, (sysCfg.value_units) ? " W" : "");
}
else if (!strcmp(type,"VOLTAGELOW")) {
if ((data_len > 0) && (payload >= 0) && (payload < 501)) {
sysCfg.hlw_umin = payload;
}
snprintf_P(svalue, ssvalue, PSTR("{\"VoltageLow\":\"%d%s\"}"), sysCfg.hlw_umin, (sysCfg.value_units) ? " V" : "");
}
else if (!strcmp(type,"VOLTAGEHIGH")) {
if ((data_len > 0) && (payload >= 0) && (payload < 501)) {
sysCfg.hlw_umax = payload;
}
snprintf_P(svalue, ssvalue, PSTR("[\"VoltageHigh\":\"%d%s\"}"), sysCfg.hlw_umax, (sysCfg.value_units) ? " V" : "");
}
else if (!strcmp(type,"CURRENTLOW")) {
if ((data_len > 0) && (payload >= 0) && (payload < 16001)) {
sysCfg.hlw_imin = payload;
}
snprintf_P(svalue, ssvalue, PSTR("{\"CurrentLow\":\"%d%s\"}"), sysCfg.hlw_imin, (sysCfg.value_units) ? " mA" : "");
}
else if (!strcmp(type,"CURRENTHIGH")) {
if ((data_len > 0) && (payload >= 0) && (payload < 16001)) {
sysCfg.hlw_imax = payload;
}
snprintf_P(svalue, ssvalue, PSTR("{\"CurrentHigh\":\"%d%s\"}"), sysCfg.hlw_imax, (sysCfg.value_units) ? " mA" : "");
}
else if (!strcmp(type,"HLWPCAL")) {
if ((data_len > 0) && (payload > 0) && (payload < 32001)) {
sysCfg.hlw_pcal = (payload > 9999) ? payload : HLW_PREF_PULSE; // 12530
}
snprintf_P(svalue, ssvalue, PSTR("(\"HlwPcal\":\"%d%s\"}"), sysCfg.hlw_pcal, (sysCfg.value_units) ? " uS" : "");
}
else if (!strcmp(type,"HLWUCAL")) {
if ((data_len > 0) && (payload > 0) && (payload < 32001)) {
sysCfg.hlw_ucal = (payload > 999) ? payload : HLW_UREF_PULSE; // 1950
}
snprintf_P(svalue, ssvalue, PSTR("{\"HlwUcal\":\"%d%s\"}"), sysCfg.hlw_ucal, (sysCfg.value_units) ? " uS" : "");
}
else if (!strcmp(type,"HLWICAL")) {
if ((data_len > 0) && (payload > 0) && (payload < 32001)) {
sysCfg.hlw_ical = (payload > 2499) ? payload : HLW_IREF_PULSE; // 3500
}
snprintf_P(svalue, ssvalue, PSTR("{\"HlwIcal\":\"%d%s\"}"), sysCfg.hlw_ical, (sysCfg.value_units) ? " uS" : "");
}
#if FEATURE_POWER_LIMIT
else if (!strcmp(type,"MAXPOWER")) {
if ((data_len > 0) && (payload >= 0) && (payload < 3601)) {
sysCfg.hlw_mpl = payload;
}
snprintf_P(svalue, ssvalue, PSTR("{\"MaxPower\":\"%d%s\"}"), sysCfg.hlw_mpl, (sysCfg.value_units) ? " W" : "");
}
else if (!strcmp(type,"MAXPOWERHOLD")) {
if ((data_len > 0) && (payload >= 0) && (payload < 3601)) {
sysCfg.hlw_mplh = (1 == payload) ? MAX_POWER_HOLD : payload;
}
snprintf_P(svalue, ssvalue, PSTR("{\"MaxPowerHold\":\"%d%s\"}"), sysCfg.hlw_mplh, (sysCfg.value_units) ? " Sec" : "");
}
else if (!strcmp(type,"MAXPOWERWINDOW")) {
if ((data_len > 0) && (payload >= 0) && (payload < 3601)) {
sysCfg.hlw_mplw = (1 == payload) ? MAX_POWER_WINDOW : payload;
}
snprintf_P(svalue, ssvalue, PSTR("{\"MaxPowerWindow\":\"%d%s\"}"), sysCfg.hlw_mplw, (sysCfg.value_units) ? " Sec" : "");
}
else if (!strcmp(type,"SAFEPOWER")) {
if ((data_len > 0) && (payload >= 0) && (payload < 3601)) {
sysCfg.hlw_mspl = payload;
}
snprintf_P(svalue, ssvalue, PSTR("{\"SafePower\":\"%d%s\"}"), sysCfg.hlw_mspl, (sysCfg.value_units) ? " W" : "");
}
else if (!strcmp(type,"SAFEPOWERHOLD")) {
if ((data_len > 0) && (payload >= 0) && (payload < 3601)) {
sysCfg.hlw_msplh = (1 == payload) ? SAFE_POWER_HOLD : payload;
}
snprintf_P(svalue, ssvalue, PSTR("{\"SafePowerHold\":\"%d%s\"}"), sysCfg.hlw_msplh, (sysCfg.value_units) ? " Sec" : "");
}
else if (!strcmp(type,"SAFEPOWERWINDOW")) {
if ((data_len > 0) && (payload >= 0) && (payload < 1440)) {
sysCfg.hlw_msplw = (1 == payload) ? SAFE_POWER_WINDOW : payload;
}
snprintf_P(svalue, ssvalue, PSTR("{\"SafePowerWindow\":\"%d%s\"}"), sysCfg.hlw_msplw, (sysCfg.value_units) ? " Min" : "");
}
else if (!strcmp(type,"MAXENERGY")) {
if ((data_len > 0) && (payload >= 0) && (payload < 3601)) {
sysCfg.hlw_mkwh = payload;
hlw_mkwh_state = 3;
}
snprintf_P(svalue, ssvalue, PSTR("{\"MaxEnergy\":\"%d%s\"}"), sysCfg.hlw_mkwh, (sysCfg.value_units) ? " Wh" : "");
}
else if (!strcmp(type,"MAXENERGYSTART")) {
if ((data_len > 0) && (payload >= 0) && (payload < 24)) {
sysCfg.hlw_mkwhs = payload;
}
snprintf_P(svalue, ssvalue, PSTR("{\"MaxEnergyStart\":\"%d%s\"}"), sysCfg.hlw_mkwhs, (sysCfg.value_units) ? " Hr" : "");
}
#endif // FEATURE_POWER_LIMIT
else {
serviced = false;
}
return serviced;
}
/*********************************************************************************************\
* Presentation
\*********************************************************************************************/
void hlw_mqttStat(byte option, char* svalue, uint16_t ssvalue)
{
char stemp0[10];
char stemp1[10];
char stemp2[10];
char stemp3[10];
char speriod[20];
float ped;
float pi;
float pc;
uint16_t pe;
uint16_t pw;
uint16_t pu;
hlw_readEnergy(option, ped, pe, pw, pu, pi, pc);
dtostrf((float)sysCfg.hlw_kWhyesterday / 100000000, 1, ENERGY_RESOLUTION &7, stemp0);
dtostrf(ped, 1, ENERGY_RESOLUTION &7, stemp1);
dtostrf(pc, 1, 2, stemp2);
dtostrf(pi, 1, 3, stemp3);
snprintf_P(speriod, sizeof(speriod), PSTR(", \"Period\":%d"), pe);
snprintf_P(svalue, ssvalue, PSTR("%s\"Yesterday\":%s, \"Today\":%s%s, \"Power\":%d, \"Factor\":%s, \"Voltage\":%d, \"Current\":%s}"),
svalue, stemp0, stemp1, (option) ? speriod : "", pw, stemp2, pu, stemp3);
#ifdef USE_DOMOTICZ
dtostrf(ped * 1000, 1, 1, stemp1);
domoticz_sensor4(pw, stemp1);
#endif // USE_DOMOTICZ
}
void hlw_mqttPresent()
{
// {"Time":"2017-03-04T13:37:24", "Yesterday":0.013, "Today":0.000, "Period":0, "Power":0, "Factor":0.00, "Voltage":0, "Current":0.000}
char svalue[200]; // was MESSZ
snprintf_P(svalue, sizeof(svalue), PSTR("{\"Time\":\"%s\", "), getDateTime().c_str());
hlw_mqttStat(1, svalue, sizeof(svalue));
mqtt_publish_topic_P(1, PSTR("ENERGY"), svalue);
}
void hlw_mqttStatus(char* svalue, uint16_t ssvalue)
{
snprintf_P(svalue, ssvalue, PSTR("{\"StatusPWR\":{"));
hlw_mqttStat(0, svalue, ssvalue);
snprintf_P(svalue, ssvalue, PSTR("%s}"), svalue);
}
#ifdef USE_WEBSERVER
const char HTTP_ENERGY_SNS[] PROGMEM =
"<tr><th>Voltage</th><td>%d V</td></tr>"
"<tr><th>Current</th><td>%s A</td></tr>"
"<tr><th>Power</th><td>%d W</td></tr>"
"<tr><th>Power Factor</th><td>%s</td></tr>"
"<tr><th>Energy Today</th><td>%s kWh</td></tr>"
"<tr><th>Energy Yesterday</th><td>%s kWh</td></tr>";
String hlw_webPresent()
{
String page = "";
char stemp[10];
char stemp2[10];
char stemp3[10];
char stemp4[10];
char sensor[300];
float ped;
float pi;
float pc;
uint16_t pe;
uint16_t pw;
uint16_t pu;
hlw_readEnergy(0, ped, pe, pw, pu, pi, pc);
dtostrf(pi, 1, 3, stemp);
dtostrf(pc, 1, 2, stemp2);
dtostrf(ped, 1, ENERGY_RESOLUTION &7, stemp3);
dtostrf((float)sysCfg.hlw_kWhyesterday / 100000000, 1, ENERGY_RESOLUTION &7, stemp4);
snprintf_P(sensor, sizeof(sensor), HTTP_ENERGY_SNS, pu, stemp, pw, stemp2, stemp3, stemp4);
page += sensor;
return page;
}
#endif // USE_WEBSERVER
Reference in New Issue View Git Blame Copy Permalink