Tasmota/tasmota/support.ino

1824 lines
51 KiB
C++
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

/*
support.ino - support for Tasmota
Copyright (C) 2020 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 <http://www.gnu.org/licenses/>.
*/
IPAddress syslog_host_addr; // Syslog host IP address
uint32_t syslog_host_hash = 0; // Syslog host name hash
extern "C" {
extern struct rst_info resetInfo;
}
/*********************************************************************************************\
* Watchdog extension (https://github.com/esp8266/Arduino/issues/1532)
\*********************************************************************************************/
#include <Ticker.h>
Ticker tickerOSWatch;
const uint32_t OSWATCH_RESET_TIME = 120;
static unsigned long oswatch_last_loop_time;
uint8_t oswatch_blocked_loop = 0;
#ifndef USE_WS2812_DMA // Collides with Neopixelbus but solves exception
//void OsWatchTicker() ICACHE_RAM_ATTR;
#endif // USE_WS2812_DMA
#ifdef USE_KNX
bool knx_started = false;
#endif // USE_KNX
void OsWatchTicker(void)
{
uint32_t t = millis();
uint32_t last_run = abs(t - oswatch_last_loop_time);
#ifdef DEBUG_THEO
int32_t rssi = WiFi.RSSI();
AddLog_P2(LOG_LEVEL_DEBUG, PSTR(D_LOG_APPLICATION D_OSWATCH " FreeRam %d, rssi %d %% (%d dBm), last_run %d"), ESP.getFreeHeap(), WifiGetRssiAsQuality(rssi), rssi, last_run);
#endif // DEBUG_THEO
if (last_run >= (OSWATCH_RESET_TIME * 1000)) {
// AddLog_P(LOG_LEVEL_INFO, PSTR(D_LOG_APPLICATION D_OSWATCH " " D_BLOCKED_LOOP ". " D_RESTARTING)); // Save iram space
RtcSettings.oswatch_blocked_loop = 1;
RtcSettingsSave();
// ESP.restart(); // normal reboot
// ESP.reset(); // hard reset
// Force an exception to get a stackdump
volatile uint32_t dummy;
dummy = *((uint32_t*) 0x00000000);
}
}
void OsWatchInit(void)
{
oswatch_blocked_loop = RtcSettings.oswatch_blocked_loop;
RtcSettings.oswatch_blocked_loop = 0;
oswatch_last_loop_time = millis();
tickerOSWatch.attach_ms(((OSWATCH_RESET_TIME / 3) * 1000), OsWatchTicker);
}
void OsWatchLoop(void)
{
oswatch_last_loop_time = millis();
// while(1) delay(1000); // this will trigger the os watch
}
bool OsWatchBlockedLoop(void)
{
return oswatch_blocked_loop;
}
uint32_t ResetReason(void)
{
/*
user_interface.h
REASON_DEFAULT_RST = 0, // "Power on" normal startup by power on
REASON_WDT_RST = 1, // "Hardware Watchdog" hardware watch dog reset
REASON_EXCEPTION_RST = 2, // "Exception" exception reset, GPIO status wont change
REASON_SOFT_WDT_RST = 3, // "Software Watchdog" software watch dog reset, GPIO status wont change
REASON_SOFT_RESTART = 4, // "Software/System restart" software restart ,system_restart , GPIO status wont change
REASON_DEEP_SLEEP_AWAKE = 5, // "Deep-Sleep Wake" wake up from deep-sleep
REASON_EXT_SYS_RST = 6 // "External System" external system reset
*/
#ifdef ESP8266
return resetInfo.reason;
#else
return ESP_ResetInfoReason();
#endif
}
String GetResetReason(void)
{
if (oswatch_blocked_loop) {
char buff[32];
strncpy_P(buff, PSTR(D_JSON_BLOCKED_LOOP), sizeof(buff));
return String(buff);
} else {
return ESP_getResetReason();
}
}
/*********************************************************************************************\
* Miscellaneous
\*********************************************************************************************/
// Get span until single character in string
size_t strchrspn(const char *str1, int character)
{
size_t ret = 0;
char *start = (char*)str1;
char *end = strchr(str1, character);
if (end) ret = end - start;
return ret;
}
// Function to return a substring defined by a delimiter at an index
char* subStr(char* dest, char* str, const char *delim, int index)
{
char *act;
char *sub = nullptr;
char *ptr;
int i;
// Since strtok consumes the first arg, make a copy
strncpy(dest, str, strlen(str)+1);
for (i = 1, act = dest; i <= index; i++, act = nullptr) {
sub = strtok_r(act, delim, &ptr);
if (sub == nullptr) break;
}
sub = Trim(sub);
return sub;
}
float CharToFloat(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
float left = 0;
if (*pt != '.') {
left = atoi(pt); // Get left part
while (isdigit(*pt)) { pt++; } // Skip number
}
float right = 0;
if (*pt == '.') {
pt++;
right = atoi(pt); // Decimal part
while (isdigit(*pt)) {
pt++;
right /= 10.0f;
}
}
float result = left + right;
if (sign < 0) {
return -result; // Add negative sign
}
return result;
}
int TextToInt(char *str)
{
char *p;
uint8_t radix = 10;
if ('#' == str[0]) {
radix = 16;
str++;
}
return strtol(str, &p, radix);
}
char* ulltoa(unsigned long long value, char *str, int radix)
{
char digits[64];
char *dst = str;
int i = 0;
// if (radix < 2 || radix > 36) { radix = 10; }
do {
int n = value % radix;
digits[i++] = (n < 10) ? (char)n+'0' : (char)n-10+'A';
value /= radix;
} while (value != 0);
while (i > 0) { *dst++ = digits[--i]; }
*dst = 0;
return str;
}
// see https://stackoverflow.com/questions/6357031/how-do-you-convert-a-byte-array-to-a-hexadecimal-string-in-c
// char* ToHex_P(unsigned char * in, size_t insz, char * out, size_t outsz, char inbetween = '\0'); in tasmota_globals.h
char* ToHex_P(const unsigned char * in, size_t insz, char * out, size_t outsz, char inbetween)
{
// ToHex_P(in, insz, out, outz) -> "12345667"
// ToHex_P(in, insz, out, outz, ' ') -> "12 34 56 67"
// ToHex_P(in, insz, out, outz, ':') -> "12:34:56:67"
static const char * hex = "0123456789ABCDEF";
int between = (inbetween) ? 3 : 2;
const unsigned char * pin = in;
char * pout = out;
for (; pin < in+insz; pout += between, pin++) {
pout[0] = hex[(pgm_read_byte(pin)>>4) & 0xF];
pout[1] = hex[ pgm_read_byte(pin) & 0xF];
if (inbetween) { pout[2] = inbetween; }
if (pout + 3 - out > outsz) { break; } // Better to truncate output string than overflow buffer
}
pout[(inbetween && insz) ? -1 : 0] = 0; // Discard last inbetween if any input
return out;
}
char* Uint64toHex(uint64_t value, char *str, uint16_t bits)
{
ulltoa(value, str, 16); // Get 64bit value
int fill = 8;
if ((bits > 3) && (bits < 65)) {
fill = bits / 4; // Max 16
if (bits % 4) { fill++; }
}
int len = strlen(str);
fill -= len;
if (fill > 0) {
memmove(str + fill, str, len +1);
memset(str, '0', fill);
}
return str;
}
char* dtostrfd(double number, unsigned char prec, char *s)
{
if ((isnan(number)) || (isinf(number))) { // Fix for JSON output (https://stackoverflow.com/questions/1423081/json-left-out-infinity-and-nan-json-status-in-ecmascript)
strcpy(s, "null");
return s;
} else {
return dtostrf(number, 1, prec, s);
}
}
char* Unescape(char* buffer, uint32_t* size)
{
uint8_t* read = (uint8_t*)buffer;
uint8_t* write = (uint8_t*)buffer;
int32_t start_size = *size;
int32_t end_size = *size;
uint8_t che = 0;
// AddLogBuffer(LOG_LEVEL_DEBUG, (uint8_t*)buffer, *size);
while (start_size > 0) {
uint8_t ch = *read++;
start_size--;
if (ch != '\\') {
*write++ = ch;
} else {
if (start_size > 0) {
uint8_t chi = *read++;
start_size--;
end_size--;
switch (chi) {
case '\\': che = '\\'; break; // 5C Backslash
case 'a': che = '\a'; break; // 07 Bell (Alert)
case 'b': che = '\b'; break; // 08 Backspace
case 'e': che = '\e'; break; // 1B Escape
case 'f': che = '\f'; break; // 0C Formfeed
case 'n': che = '\n'; break; // 0A Linefeed (Newline)
case 'r': che = '\r'; break; // 0D Carriage return
case 's': che = ' '; break; // 20 Space
case 't': che = '\t'; break; // 09 Horizontal tab
case 'v': che = '\v'; break; // 0B Vertical tab
case 'x': {
uint8_t* start = read;
che = (uint8_t)strtol((const char*)read, (char**)&read, 16);
start_size -= (uint16_t)(read - start);
end_size -= (uint16_t)(read - start);
break;
}
case '"': che = '\"'; break; // 22 Quotation mark
// case '?': che = '\?'; break; // 3F Question mark
default : {
che = chi;
*write++ = ch;
end_size++;
}
}
*write++ = che;
}
}
}
*size = end_size;
*write++ = 0; // add the end string pointer reference
// AddLogBuffer(LOG_LEVEL_DEBUG, (uint8_t*)buffer, *size);
return buffer;
}
char* RemoveSpace(char* p)
{
char* write = p;
char* read = p;
char ch = '.';
while (ch != '\0') {
ch = *read++;
if (!isspace(ch)) {
*write++ = ch;
}
}
// *write = '\0'; // Removed 20190223 as it buffer overflows on no isspace found - no need either
return p;
}
char* ReplaceCommaWithDot(char* p)
{
char* write = (char*)p;
char* read = (char*)p;
char ch = '.';
while (ch != '\0') {
ch = *read++;
if (ch == ',') {
ch = '.';
}
*write++ = ch;
}
return p;
}
char* LowerCase(char* dest, const char* source)
{
char* write = dest;
const char* read = source;
char ch = '.';
while (ch != '\0') {
ch = *read++;
*write++ = tolower(ch);
}
return dest;
}
char* UpperCase(char* dest, const char* source)
{
char* write = dest;
const char* read = source;
char ch = '.';
while (ch != '\0') {
ch = *read++;
*write++ = toupper(ch);
}
return dest;
}
char* UpperCase_P(char* dest, const char* source)
{
char* write = dest;
const char* read = source;
char ch = '.';
while (ch != '\0') {
ch = pgm_read_byte(read++);
*write++ = toupper(ch);
}
return dest;
}
char* Trim(char* p)
{
while ((*p != '\0') && isblank(*p)) { p++; } // Trim leading spaces
char* q = p + strlen(p) -1;
while ((q >= p) && isblank(*q)) { q--; } // Trim trailing spaces
q++;
*q = '\0';
return p;
}
char* RemoveAllSpaces(char* p)
{
// remove any white space from the base64
char *cursor = p;
uint32_t offset = 0;
while (1) {
*cursor = *(cursor + offset);
if ((' ' == *cursor) || ('\t' == *cursor) || ('\n' == *cursor)) { // if space found, remove this char until end of string
offset++;
} else {
if (0 == *cursor) { break; }
cursor++;
}
}
return p;
}
char* NoAlNumToUnderscore(char* dest, const char* source)
{
char* write = dest;
const char* read = source;
char ch = '.';
while (ch != '\0') {
ch = *read++;
*write++ = (isalnum(ch) || ('\0' == ch)) ? ch : '_';
}
return dest;
}
char IndexSeparator(void)
{
/*
// 20 bytes more costly !?!
const char separators[] = { "-_" };
return separators[Settings.flag3.use_underscore];
*/
if (Settings.flag3.use_underscore) { // SetOption64 - Enable "_" instead of "-" as sensor index separator
return '_';
} else {
return '-';
}
}
void SetShortcutDefault(void)
{
if ('\0' != XdrvMailbox.data[0]) { // There must be at least one character in the buffer
XdrvMailbox.data[0] = '0' + SC_DEFAULT; // SC_CLEAR, SC_DEFAULT, SC_USER
XdrvMailbox.data[1] = '\0';
}
}
uint8_t Shortcut(void)
{
uint8_t result = 10;
if ('\0' == XdrvMailbox.data[1]) { // Only allow single character input for shortcut
if (('"' == XdrvMailbox.data[0]) || ('0' == XdrvMailbox.data[0])) {
result = SC_CLEAR;
} else {
result = atoi(XdrvMailbox.data); // 1 = SC_DEFAULT, 2 = SC_USER
if (0 == result) {
result = 10;
}
}
}
return result;
}
bool ValidIpAddress(const char* str)
{
const char* p = str;
while (*p && ((*p == '.') || ((*p >= '0') && (*p <= '9')))) { p++; }
return (*p == '\0');
}
bool ParseIp(uint32_t* addr, const char* str)
{
uint8_t *part = (uint8_t*)addr;
uint8_t i;
*addr = 0;
for (i = 0; i < 4; i++) {
part[i] = strtoul(str, nullptr, 10); // Convert byte
str = strchr(str, '.');
if (str == nullptr || *str == '\0') {
break; // No more separators, exit
}
str++; // Point to next character after separator
}
return (3 == i);
}
uint32_t ParseParameters(uint32_t count, uint32_t *params)
{
char *p;
uint32_t i = 0;
for (char *str = strtok_r(XdrvMailbox.data, ", ", &p); str && i < count; str = strtok_r(nullptr, ", ", &p), i++) {
params[i] = strtoul(str, nullptr, 0);
}
return i;
}
// Function to parse & check if version_str is newer than our currently installed version.
bool NewerVersion(char* version_str)
{
uint32_t version = 0;
uint32_t i = 0;
char *str_ptr;
char version_dup[strlen(version_str) +1];
strncpy(version_dup, version_str, sizeof(version_dup)); // Duplicate the version_str as strtok_r will modify it.
// Loop through the version string, splitting on '.' seperators.
for (char *str = strtok_r(version_dup, ".", &str_ptr); str && i < sizeof(VERSION); str = strtok_r(nullptr, ".", &str_ptr), i++) {
int field = atoi(str);
// The fields in a version string can only range from 0-255.
if ((field < 0) || (field > 255)) {
return false;
}
// Shuffle the accumulated bytes across, and add the new byte.
version = (version << 8) + field;
// Check alpha delimiter after 1.2.3 only
if ((2 == i) && isalpha(str[strlen(str)-1])) {
field = str[strlen(str)-1] & 0x1f;
version = (version << 8) + field;
i++;
}
}
// A version string should have 2-4 fields. e.g. 1.2, 1.2.3, or 1.2.3a (= 1.2.3.1).
// If not, then don't consider it a valid version string.
if ((i < 2) || (i > sizeof(VERSION))) {
return false;
}
// Keep shifting the parsed version until we hit the maximum number of tokens.
// VERSION stores the major number of the version in the most significant byte of the uint32_t.
while (i < sizeof(VERSION)) {
version <<= 8;
i++;
}
// Now we should have a fully constructed version number in uint32_t form.
return (version > VERSION);
}
char* GetPowerDevice(char* dest, uint32_t idx, size_t size, uint32_t option)
{
strncpy_P(dest, S_RSLT_POWER, size); // POWER
if ((devices_present + option) > 1) {
char sidx[8];
snprintf_P(sidx, sizeof(sidx), PSTR("%d"), idx); // x
strncat(dest, sidx, size - strlen(dest) -1); // POWERx
}
return dest;
}
char* GetPowerDevice(char* dest, uint32_t idx, size_t size)
{
return GetPowerDevice(dest, idx, size, 0);
}
void GetEspHardwareType(void)
{
#ifdef ESP8266
// esptool.py get_efuses
uint32_t efuse1 = *(uint32_t*)(0x3FF00050);
uint32_t efuse2 = *(uint32_t*)(0x3FF00054);
// uint32_t efuse3 = *(uint32_t*)(0x3FF00058);
// uint32_t efuse4 = *(uint32_t*)(0x3FF0005C);
is_8285 = ( (efuse1 & (1 << 4)) || (efuse2 & (1 << 16)) );
if (is_8285 && (ESP.getFlashChipRealSize() > 1048576)) {
is_8285 = false; // ESP8285 can only have 1M flash
}
#else
is_8285 = false; // ESP8285 can only have 1M flash
#endif
}
String GetDeviceHardware(void)
{
char buff[10];
#ifdef ESP8266
if (is_8285) {
strcpy_P(buff, PSTR("ESP8285"));
} else {
strcpy_P(buff, PSTR("ESP8266EX"));
}
#else
strcpy_P(buff, PSTR("ESP32"));
#endif
return String(buff);
}
float ConvertTemp(float c)
{
float result = c;
global_update = uptime;
global_temperature = c;
if (!isnan(c) && Settings.flag.temperature_conversion) { // SetOption8 - Switch between Celsius or Fahrenheit
result = c * 1.8 + 32; // Fahrenheit
}
result = result + (0.1 * Settings.temp_comp);
return result;
}
float ConvertTempToCelsius(float c)
{
float result = c;
if (!isnan(c) && Settings.flag.temperature_conversion) { // SetOption8 - Switch between Celsius or Fahrenheit
result = (c - 32) / 1.8; // Celsius
}
result = result + (0.1 * Settings.temp_comp);
return result;
}
char TempUnit(void)
{
return (Settings.flag.temperature_conversion) ? 'F' : 'C'; // SetOption8 - Switch between Celsius or Fahrenheit
}
float ConvertHumidity(float h)
{
float result = h;
global_update = uptime;
global_humidity = h;
result = result + (0.1 * Settings.hum_comp);
return result;
}
float CalcTempHumToDew(float t, float h)
{
if (isnan(h) || isnan(t)) { return 0.0; }
if (Settings.flag.temperature_conversion) { // SetOption8 - Switch between Celsius or Fahrenheit
t = (t - 32) / 1.8; // Celsius
}
float gamma = TaylorLog(h / 100) + 17.62 * t / (243.5 + t);
float result = (243.5 * gamma / (17.62 - gamma));
if (Settings.flag.temperature_conversion) { // SetOption8 - Switch between Celsius or Fahrenheit
result = result * 1.8 + 32; // Fahrenheit
}
return result;
}
float ConvertPressure(float p)
{
float result = p;
global_update = uptime;
global_pressure = p;
if (!isnan(p) && Settings.flag.pressure_conversion) { // SetOption24 - Switch between hPa or mmHg pressure unit
result = p * 0.75006375541921; // mmHg
}
return result;
}
String PressureUnit(void)
{
return (Settings.flag.pressure_conversion) ? String(D_UNIT_MILLIMETER_MERCURY) : String(D_UNIT_PRESSURE);
}
float ConvertSpeed(float s)
{
// Entry in m/s
return s * kSpeedConversionFactor[Settings.flag2.speed_conversion];
}
String SpeedUnit(void)
{
char speed[8];
return String(GetTextIndexed(speed, sizeof(speed), Settings.flag2.speed_conversion, kSpeedUnit));
}
void ResetGlobalValues(void)
{
if ((uptime - global_update) > GLOBAL_VALUES_VALID) { // Reset after 5 minutes
global_update = 0;
global_temperature = 9999;
global_humidity = 0;
global_pressure = 0;
}
}
uint32_t SqrtInt(uint32_t num)
{
if (num <= 1) {
return num;
}
uint32_t x = num / 2;
uint32_t y;
do {
y = (x + num / x) / 2;
if (y >= x) {
return x;
}
x = y;
} while (true);
}
uint32_t RoundSqrtInt(uint32_t num)
{
uint32_t s = SqrtInt(4 * num);
if (s & 1) {
s++;
}
return s / 2;
}
char* GetTextIndexed(char* destination, size_t destination_size, uint32_t index, const char* haystack)
{
// Returns empty string if not found
// Returns text of found
char* write = destination;
const char* read = haystack;
index++;
while (index--) {
size_t size = destination_size -1;
write = destination;
char ch = '.';
while ((ch != '\0') && (ch != '|')) {
ch = pgm_read_byte(read++);
if (size && (ch != '|')) {
*write++ = ch;
size--;
}
}
if (0 == ch) {
if (index) {
write = destination;
}
break;
}
}
*write = '\0';
return destination;
}
int GetCommandCode(char* destination, size_t destination_size, const char* needle, const char* haystack)
{
// Returns -1 of not found
// Returns index and command if found
int result = -1;
const char* read = haystack;
char* write = destination;
while (true) {
result++;
size_t size = destination_size -1;
write = destination;
char ch = '.';
while ((ch != '\0') && (ch != '|')) {
ch = pgm_read_byte(read++);
if (size && (ch != '|')) {
*write++ = ch;
size--;
}
}
*write = '\0';
if (!strcasecmp(needle, destination)) {
break;
}
if (0 == ch) {
result = -1;
break;
}
}
return result;
}
bool DecodeCommand(const char* haystack, void (* const MyCommand[])(void))
{
GetTextIndexed(XdrvMailbox.command, CMDSZ, 0, haystack); // Get prefix if available
int prefix_length = strlen(XdrvMailbox.command);
if (prefix_length) {
char prefix[prefix_length +1];
snprintf_P(prefix, sizeof(prefix), XdrvMailbox.topic); // Copy prefix part only
if (strcasecmp(prefix, XdrvMailbox.command)) {
return false; // Prefix not in command
}
}
int command_code = GetCommandCode(XdrvMailbox.command + prefix_length, CMDSZ, XdrvMailbox.topic + prefix_length, haystack);
if (command_code > 0) { // Skip prefix
XdrvMailbox.command_code = command_code -1;
MyCommand[XdrvMailbox.command_code]();
return true;
}
return false;
}
const char kOptions[] PROGMEM = "OFF|" D_OFF "|FALSE|" D_FALSE "|STOP|" D_STOP "|" D_CELSIUS "|" // 0
"ON|" D_ON "|TRUE|" D_TRUE "|START|" D_START "|" D_FAHRENHEIT "|" D_USER "|" // 1
"TOGGLE|" D_TOGGLE "|" D_ADMIN "|" // 2
"BLINK|" D_BLINK "|" // 3
"BLINKOFF|" D_BLINKOFF "|" // 4
"ALL" ; // 255
const uint8_t sNumbers[] PROGMEM = { 0,0,0,0,0,0,0,
1,1,1,1,1,1,1,1,
2,2,2,
3,3,
4,4,
255 };
int GetStateNumber(char *state_text)
{
char command[CMDSZ];
int state_number = GetCommandCode(command, sizeof(command), state_text, kOptions);
if (state_number >= 0) {
state_number = pgm_read_byte(sNumbers + state_number);
}
return state_number;
}
String GetSerialConfig(void)
{
// Settings.serial_config layout
// b000000xx - 5, 6, 7 or 8 data bits
// b00000x00 - 1 or 2 stop bits
// b000xx000 - None, Even or Odd parity
const char kParity[] = "NEOI";
char config[4];
config[0] = '5' + (Settings.serial_config & 0x3);
config[1] = kParity[(Settings.serial_config >> 3) & 0x3];
config[2] = '1' + ((Settings.serial_config >> 2) & 0x1);
config[3] = '\0';
return String(config);
}
void SetSerialBegin()
{
uint32_t baudrate = Settings.baudrate * 300;
AddLog_P2(LOG_LEVEL_INFO, PSTR(D_LOG_SERIAL "Set to %s %d bit/s"), GetSerialConfig().c_str(), baudrate);
Serial.flush();
Serial.begin(baudrate, (SerialConfig)pgm_read_byte(kTasmotaSerialConfig + Settings.serial_config));
}
void SetSerialConfig(uint32_t serial_config)
{
if (serial_config > TS_SERIAL_8O2) {
serial_config = TS_SERIAL_8N1;
}
if (serial_config != Settings.serial_config) {
Settings.serial_config = serial_config;
SetSerialBegin();
}
}
void SetSerialBaudrate(uint32_t baudrate)
{
Settings.baudrate = baudrate / 300;
if (Serial.baudRate() != baudrate) {
SetSerialBegin();
}
}
void SetSerial(uint32_t baudrate, uint32_t serial_config)
{
Settings.flag.mqtt_serial = 0; // CMND_SERIALSEND and CMND_SERIALLOG
Settings.serial_config = serial_config;
Settings.baudrate = baudrate / 300;
SetSeriallog(LOG_LEVEL_NONE);
SetSerialBegin();
}
void ClaimSerial(void)
{
serial_local = true;
AddLog_P(LOG_LEVEL_INFO, PSTR("SNS: Hardware Serial"));
SetSeriallog(LOG_LEVEL_NONE);
Settings.baudrate = Serial.baudRate() / 300;
}
void SerialSendRaw(char *codes)
{
char *p;
char stemp[3];
uint8_t code;
int size = strlen(codes);
while (size > 1) {
strlcpy(stemp, codes, sizeof(stemp));
code = strtol(stemp, &p, 16);
Serial.write(code);
size -= 2;
codes += 2;
}
}
uint32_t GetHash(const char *buffer, size_t size)
{
uint32_t hash = 0;
for (uint32_t i = 0; i <= size; i++) {
hash += (uint8_t)*buffer++ * (i +1);
}
return hash;
}
void ShowSource(uint32_t source)
{
if ((source > 0) && (source < SRC_MAX)) {
char stemp1[20];
AddLog_P2(LOG_LEVEL_DEBUG, PSTR("SRC: %s"), GetTextIndexed(stemp1, sizeof(stemp1), source, kCommandSource));
}
}
void WebHexCode(uint32_t i, const char* code)
{
char scolor[10];
strlcpy(scolor, code, sizeof(scolor));
char* p = scolor;
if ('#' == p[0]) { p++; } // Skip
if (3 == strlen(p)) { // Convert 3 character to 6 character color code
p[6] = p[3]; // \0
p[5] = p[2]; // 3
p[4] = p[2]; // 3
p[3] = p[1]; // 2
p[2] = p[1]; // 2
p[1] = p[0]; // 1
}
uint32_t color = strtol(p, nullptr, 16);
/*
if (3 == strlen(p)) { // Convert 3 character to 6 character color code
uint32_t w = ((color & 0xF00) << 8) | ((color & 0x0F0) << 4) | (color & 0x00F); // 00010203
color = w | (w << 4); // 00112233
}
*/
uint32_t j = sizeof(Settings.web_color) / 3; // First area contains j = 18 colors
/*
if (i < j) {
Settings.web_color[i][0] = (color >> 16) & 0xFF; // Red
Settings.web_color[i][1] = (color >> 8) & 0xFF; // Green
Settings.web_color[i][2] = color & 0xFF; // Blue
} else {
Settings.web_color2[i-j][0] = (color >> 16) & 0xFF; // Red
Settings.web_color2[i-j][1] = (color >> 8) & 0xFF; // Green
Settings.web_color2[i-j][2] = color & 0xFF; // Blue
}
*/
if (i >= j) {
// Calculate i to index in Settings.web_color2 - Dirty(!) but saves 128 bytes code
i += ((((uint8_t*)&Settings.web_color2 - (uint8_t*)&Settings.web_color) / 3) - j);
}
Settings.web_color[i][0] = (color >> 16) & 0xFF; // Red
Settings.web_color[i][1] = (color >> 8) & 0xFF; // Green
Settings.web_color[i][2] = color & 0xFF; // Blue
}
uint32_t WebColor(uint32_t i)
{
uint32_t j = sizeof(Settings.web_color) / 3; // First area contains j = 18 colors
/*
uint32_t tcolor = (i<j)? (Settings.web_color[i][0] << 16) | (Settings.web_color[i][1] << 8) | Settings.web_color[i][2] :
(Settings.web_color2[i-j][0] << 16) | (Settings.web_color2[i-j][1] << 8) | Settings.web_color2[i-j][2];
*/
if (i >= j) {
// Calculate i to index in Settings.web_color2 - Dirty(!) but saves 128 bytes code
i += ((((uint8_t*)&Settings.web_color2 - (uint8_t*)&Settings.web_color) / 3) - j);
}
uint32_t tcolor = (Settings.web_color[i][0] << 16) | (Settings.web_color[i][1] << 8) | Settings.web_color[i][2];
return tcolor;
}
/*********************************************************************************************\
* Response data handling
\*********************************************************************************************/
const uint16_t TIMESZ = 100; // Max number of characters in time string
char* ResponseGetTime(uint32_t format, char* time_str)
{
switch (format) {
case 1:
snprintf_P(time_str, TIMESZ, PSTR("{\"" D_JSON_TIME "\":\"%s\",\"Epoch\":%u"), GetDateAndTime(DT_LOCAL).c_str(), UtcTime());
break;
case 2:
snprintf_P(time_str, TIMESZ, PSTR("{\"" D_JSON_TIME "\":%u"), UtcTime());
break;
default:
snprintf_P(time_str, TIMESZ, PSTR("{\"" D_JSON_TIME "\":\"%s\""), GetDateAndTime(DT_LOCAL).c_str());
}
return time_str;
}
int Response_P(const char* format, ...) // Content send snprintf_P char data
{
// This uses char strings. Be aware of sending %% if % is needed
va_list args;
va_start(args, format);
int len = vsnprintf_P(mqtt_data, sizeof(mqtt_data), format, args);
va_end(args);
return len;
}
int ResponseTime_P(const char* format, ...) // Content send snprintf_P char data
{
// This uses char strings. Be aware of sending %% if % is needed
va_list args;
va_start(args, format);
ResponseGetTime(Settings.flag2.time_format, mqtt_data);
int mlen = strlen(mqtt_data);
int len = vsnprintf_P(mqtt_data + mlen, sizeof(mqtt_data) - mlen, format, args);
va_end(args);
return len + mlen;
}
int ResponseAppend_P(const char* format, ...) // Content send snprintf_P char data
{
// This uses char strings. Be aware of sending %% if % is needed
va_list args;
va_start(args, format);
int mlen = strlen(mqtt_data);
int len = vsnprintf_P(mqtt_data + mlen, sizeof(mqtt_data) - mlen, format, args);
va_end(args);
return len + mlen;
}
int ResponseAppendTimeFormat(uint32_t format)
{
char time_str[TIMESZ];
return ResponseAppend_P(ResponseGetTime(format, time_str));
}
int ResponseAppendTime(void)
{
return ResponseAppendTimeFormat(Settings.flag2.time_format);
}
int ResponseAppendTHD(float f_temperature, float f_humidity)
{
char temperature[FLOATSZ];
dtostrfd(f_temperature, Settings.flag2.temperature_resolution, temperature);
char humidity[FLOATSZ];
dtostrfd(f_humidity, Settings.flag2.humidity_resolution, humidity);
char dewpoint[FLOATSZ];
dtostrfd(CalcTempHumToDew(f_temperature, f_humidity), Settings.flag2.temperature_resolution, dewpoint);
return ResponseAppend_P(PSTR("\"" D_JSON_TEMPERATURE "\":%s,\"" D_JSON_HUMIDITY "\":%s,\"" D_JSON_DEWPOINT "\":%s"), temperature, humidity, dewpoint);
}
int ResponseJsonEnd(void)
{
return ResponseAppend_P(PSTR("}"));
}
int ResponseJsonEndEnd(void)
{
return ResponseAppend_P(PSTR("}}"));
}
/*********************************************************************************************\
* GPIO Module and Template management
\*********************************************************************************************/
void DigitalWrite(uint32_t gpio_pin, uint32_t state)
{
if (pin[gpio_pin] < 99) {
digitalWrite(pin[gpio_pin], state &1);
}
}
uint8_t ModuleNr(void)
{
// 0 = User module (255)
// 1 up = Template module 0 up
return (USER_MODULE == Settings.module) ? 0 : Settings.module +1;
}
bool ValidTemplateModule(uint32_t index)
{
for (uint32_t i = 0; i < sizeof(kModuleNiceList); i++) {
if (index == pgm_read_byte(kModuleNiceList + i)) {
return true;
}
}
return false;
}
bool ValidModule(uint32_t index)
{
if (index == USER_MODULE) { return true; }
return ValidTemplateModule(index);
}
String AnyModuleName(uint32_t index)
{
if (USER_MODULE == index) {
return String(SettingsText(SET_TEMPLATE_NAME));
} else {
char name[TOPSZ];
return String(GetTextIndexed(name, sizeof(name), index, kModuleNames));
}
}
String ModuleName(void)
{
return AnyModuleName(Settings.module);
}
void ModuleGpios(myio *gp)
{
uint8_t *dest = (uint8_t *)gp;
memset(dest, GPIO_NONE, sizeof(myio));
uint8_t src[sizeof(mycfgio)];
if (USER_MODULE == Settings.module) {
memcpy(&src, &Settings.user_template.gp, sizeof(mycfgio));
} else {
#ifdef ESP8266
memcpy_P(&src, &kModules[Settings.module].gp, sizeof(mycfgio));
#else // ESP32
memcpy_P(&src, &kModules.gp, sizeof(mycfgio));
#endif // ESP8266 - ESP32
}
// 11 85 00 85 85 00 00 00 15 38 85 00 00 81
// AddLogBuffer(LOG_LEVEL_DEBUG, (uint8_t *)&src, sizeof(mycfgio));
uint32_t j = 0;
for (uint32_t i = 0; i < sizeof(mycfgio); i++) {
if (6 == i) { j = 9; }
if (8 == i) { j = 12; }
dest[j] = src[i];
j++;
}
// 11 85 00 85 85 00 00 00 00 00 00 00 15 38 85 00 00 81
// AddLogBuffer(LOG_LEVEL_DEBUG, (uint8_t *)gp, sizeof(myio));
}
gpio_flag ModuleFlag(void)
{
gpio_flag flag;
#ifdef ESP8266
if (USER_MODULE == Settings.module) {
flag = Settings.user_template.flag;
} else {
memcpy_P(&flag, &kModules[Settings.module].flag, sizeof(gpio_flag));
}
#else // ESP32
if (USER_MODULE == Settings.module) {
/*
gpio_flag gpio_adc0;
memcpy_P(&gpio_adc0, &Settings.user_template.gp + ADC0_PIN - MIN_FLASH_PINS, sizeof(gpio_flag));
flag = Settings.user_template.flag.data + gpio_adc0.data;
*/
memcpy_P(&flag, &Settings.user_template.gp + ADC0_PIN - MIN_FLASH_PINS, sizeof(gpio_flag));
} else {
memcpy_P(&flag, &kModules.gp + ADC0_PIN - MIN_FLASH_PINS, sizeof(gpio_flag));
}
#endif // ESP8266 - ESP32
return flag;
}
void ModuleDefault(uint32_t module)
{
if (USER_MODULE == module) { module = WEMOS; } // Generic
Settings.user_template_base = module;
char name[TOPSZ];
SettingsUpdateText(SET_TEMPLATE_NAME, GetTextIndexed(name, sizeof(name), module, kModuleNames));
#ifdef ESP8266
memcpy_P(&Settings.user_template, &kModules[module], sizeof(mytmplt));
#else // ESP32
memcpy_P(&Settings.user_template, &kModules, sizeof(mytmplt));
#endif // ESP8266 - ESP32
}
void SetModuleType(void)
{
my_module_type = (USER_MODULE == Settings.module) ? Settings.user_template_base : Settings.module;
}
bool FlashPin(uint32_t pin)
{
return (((pin > 5) && (pin < 9)) || (11 == pin));
}
uint8_t ValidPin(uint32_t pin, uint32_t gpio)
{
if (FlashPin(pin)) {
return GPIO_NONE; // Disable flash pins GPIO6, GPIO7, GPIO8 and GPIO11
}
#ifdef ESP8266
// if (!is_8285 && !Settings.flag3.user_esp8285_enable) { // SetOption51 - Enable ESP8285 user GPIO's
if ((WEMOS == Settings.module) && !Settings.flag3.user_esp8285_enable) { // SetOption51 - Enable ESP8285 user GPIO's
if ((pin == 9) || (pin == 10)) {
return GPIO_NONE; // Disable possible flash GPIO9 and GPIO10
}
}
#endif // ESP8266
return gpio;
}
bool ValidGPIO(uint32_t pin, uint32_t gpio)
{
return (GPIO_USER == ValidPin(pin, gpio)); // Only allow GPIO_USER pins
}
bool ValidAdc(void)
{
gpio_flag flag = ModuleFlag();
uint32_t template_adc0 = flag.data &15;
return (ADC0_USER == template_adc0);
}
bool GetUsedInModule(uint32_t val, uint8_t *arr)
{
int offset = 0;
if (!val) { return false; } // None
if ((val >= GPIO_KEY1) && (val < GPIO_KEY1 + MAX_KEYS)) {
offset = (GPIO_KEY1_NP - GPIO_KEY1);
}
if ((val >= GPIO_KEY1_NP) && (val < GPIO_KEY1_NP + MAX_KEYS)) {
offset = -(GPIO_KEY1_NP - GPIO_KEY1);
}
if ((val >= GPIO_KEY1_INV) && (val < GPIO_KEY1_INV + MAX_KEYS)) {
offset = -(GPIO_KEY1_INV - GPIO_KEY1);
}
if ((val >= GPIO_KEY1_INV_NP) && (val < GPIO_KEY1_INV_NP + MAX_KEYS)) {
offset = -(GPIO_KEY1_INV_NP - GPIO_KEY1);
}
if ((val >= GPIO_SWT1) && (val < GPIO_SWT1 + MAX_SWITCHES)) {
offset = (GPIO_SWT1_NP - GPIO_SWT1);
}
if ((val >= GPIO_SWT1_NP) && (val < GPIO_SWT1_NP + MAX_SWITCHES)) {
offset = -(GPIO_SWT1_NP - GPIO_SWT1);
}
if ((val >= GPIO_REL1) && (val < GPIO_REL1 + MAX_RELAYS)) {
offset = (GPIO_REL1_INV - GPIO_REL1);
}
if ((val >= GPIO_REL1_INV) && (val < GPIO_REL1_INV + MAX_RELAYS)) {
offset = -(GPIO_REL1_INV - GPIO_REL1);
}
if ((val >= GPIO_LED1) && (val < GPIO_LED1 + MAX_LEDS)) {
offset = (GPIO_LED1_INV - GPIO_LED1);
}
if ((val >= GPIO_LED1_INV) && (val < GPIO_LED1_INV + MAX_LEDS)) {
offset = -(GPIO_LED1_INV - GPIO_LED1);
}
if ((val >= GPIO_PWM1) && (val < GPIO_PWM1 + MAX_PWMS)) {
offset = (GPIO_PWM1_INV - GPIO_PWM1);
}
if ((val >= GPIO_PWM1_INV) && (val < GPIO_PWM1_INV + MAX_PWMS)) {
offset = -(GPIO_PWM1_INV - GPIO_PWM1);
}
if ((val >= GPIO_CNTR1) && (val < GPIO_CNTR1 + MAX_COUNTERS)) {
offset = (GPIO_CNTR1_NP - GPIO_CNTR1);
}
if ((val >= GPIO_CNTR1_NP) && (val < GPIO_CNTR1_NP + MAX_COUNTERS)) {
offset = -(GPIO_CNTR1_NP - GPIO_CNTR1);
}
for (uint32_t i = 0; i < MAX_GPIO_PIN; i++) {
if (arr[i] == val) { return true; }
if (arr[i] == val + offset) { return true; }
}
return false;
}
bool JsonTemplate(const char* dataBuf)
{
// {"NAME":"Generic","GPIO":[17,254,29,254,7,254,254,254,138,254,139,254,254],"FLAG":1,"BASE":255}
if (strlen(dataBuf) < 9) { return false; } // Workaround exception if empty JSON like {} - Needs checks
#ifdef ESP8266
StaticJsonBuffer<400> jb; // 331 from https://arduinojson.org/v5/assistant/
#else
StaticJsonBuffer<800> jb; // 654 from https://arduinojson.org/v5/assistant/
#endif
JsonObject& obj = jb.parseObject(dataBuf);
if (!obj.success()) { return false; }
// All parameters are optional allowing for partial changes
const char* name = obj[D_JSON_NAME];
if (name != nullptr) {
SettingsUpdateText(SET_TEMPLATE_NAME, name);
}
if (obj[D_JSON_GPIO].success()) {
for (uint32_t i = 0; i < sizeof(mycfgio); i++) {
Settings.user_template.gp.io[i] = obj[D_JSON_GPIO][i] | 0;
}
}
if (obj[D_JSON_FLAG].success()) {
uint8_t flag = obj[D_JSON_FLAG] | 0;
memcpy(&Settings.user_template.flag, &flag, sizeof(gpio_flag));
}
if (obj[D_JSON_BASE].success()) {
uint8_t base = obj[D_JSON_BASE];
if ((0 == base) || !ValidTemplateModule(base -1)) { base = 18; }
Settings.user_template_base = base -1; // Default WEMOS
}
return true;
}
void TemplateJson(void)
{
Response_P(PSTR("{\"" D_JSON_NAME "\":\"%s\",\"" D_JSON_GPIO "\":["), SettingsText(SET_TEMPLATE_NAME));
for (uint32_t i = 0; i < sizeof(Settings.user_template.gp); i++) {
ResponseAppend_P(PSTR("%s%d"), (i>0)?",":"", Settings.user_template.gp.io[i]);
}
ResponseAppend_P(PSTR("],\"" D_JSON_FLAG "\":%d,\"" D_JSON_BASE "\":%d}"), Settings.user_template.flag, Settings.user_template_base +1);
}
/*********************************************************************************************\
* Sleep aware time scheduler functions borrowed from ESPEasy
\*********************************************************************************************/
inline int32_t TimeDifference(uint32_t prev, uint32_t next)
{
return ((int32_t) (next - prev));
}
int32_t TimePassedSince(uint32_t timestamp)
{
// Compute the number of milliSeconds passed since timestamp given.
// Note: value can be negative if the timestamp has not yet been reached.
return TimeDifference(timestamp, millis());
}
bool TimeReached(uint32_t timer)
{
// Check if a certain timeout has been reached.
const long passed = TimePassedSince(timer);
return (passed >= 0);
}
void SetNextTimeInterval(unsigned long& timer, const unsigned long step)
{
timer += step;
const long passed = TimePassedSince(timer);
if (passed < 0) { return; } // Event has not yet happened, which is fine.
if (static_cast<unsigned long>(passed) > step) {
// No need to keep running behind, start again.
timer = millis() + step;
return;
}
// Try to get in sync again.
timer = millis() + (step - passed);
}
int32_t TimePassedSinceUsec(uint32_t timestamp)
{
return TimeDifference(timestamp, micros());
}
bool TimeReachedUsec(uint32_t timer)
{
// Check if a certain timeout has been reached.
const long passed = TimePassedSinceUsec(timer);
return (passed >= 0);
}
/*********************************************************************************************\
* Basic I2C routines
\*********************************************************************************************/
#ifdef USE_I2C
const uint8_t I2C_RETRY_COUNTER = 3;
uint32_t i2c_active[4] = { 0 };
uint32_t i2c_buffer = 0;
bool I2cValidRead(uint8_t addr, uint8_t reg, uint8_t size)
{
uint8_t retry = I2C_RETRY_COUNTER;
bool status = false;
i2c_buffer = 0;
while (!status && retry) {
Wire.beginTransmission(addr); // start transmission to device
Wire.write(reg); // sends register address to read from
if (0 == Wire.endTransmission(false)) { // Try to become I2C Master, send data and collect bytes, keep master status for next request...
Wire.requestFrom((int)addr, (int)size); // send data n-bytes read
if (Wire.available() == size) {
for (uint32_t i = 0; i < size; i++) {
i2c_buffer = i2c_buffer << 8 | Wire.read(); // receive DATA
}
status = true;
}
}
retry--;
}
return status;
}
bool I2cValidRead8(uint8_t *data, uint8_t addr, uint8_t reg)
{
bool status = I2cValidRead(addr, reg, 1);
*data = (uint8_t)i2c_buffer;
return status;
}
bool I2cValidRead16(uint16_t *data, uint8_t addr, uint8_t reg)
{
bool status = I2cValidRead(addr, reg, 2);
*data = (uint16_t)i2c_buffer;
return status;
}
bool I2cValidReadS16(int16_t *data, uint8_t addr, uint8_t reg)
{
bool status = I2cValidRead(addr, reg, 2);
*data = (int16_t)i2c_buffer;
return status;
}
bool I2cValidRead16LE(uint16_t *data, uint8_t addr, uint8_t reg)
{
uint16_t ldata;
bool status = I2cValidRead16(&ldata, addr, reg);
*data = (ldata >> 8) | (ldata << 8);
return status;
}
bool I2cValidReadS16_LE(int16_t *data, uint8_t addr, uint8_t reg)
{
uint16_t ldata;
bool status = I2cValidRead16LE(&ldata, addr, reg);
*data = (int16_t)ldata;
return status;
}
bool I2cValidRead24(int32_t *data, uint8_t addr, uint8_t reg)
{
bool status = I2cValidRead(addr, reg, 3);
*data = i2c_buffer;
return status;
}
uint8_t I2cRead8(uint8_t addr, uint8_t reg)
{
I2cValidRead(addr, reg, 1);
return (uint8_t)i2c_buffer;
}
uint16_t I2cRead16(uint8_t addr, uint8_t reg)
{
I2cValidRead(addr, reg, 2);
return (uint16_t)i2c_buffer;
}
int16_t I2cReadS16(uint8_t addr, uint8_t reg)
{
I2cValidRead(addr, reg, 2);
return (int16_t)i2c_buffer;
}
uint16_t I2cRead16LE(uint8_t addr, uint8_t reg)
{
I2cValidRead(addr, reg, 2);
uint16_t temp = (uint16_t)i2c_buffer;
return (temp >> 8) | (temp << 8);
}
int16_t I2cReadS16_LE(uint8_t addr, uint8_t reg)
{
return (int16_t)I2cRead16LE(addr, reg);
}
int32_t I2cRead24(uint8_t addr, uint8_t reg)
{
I2cValidRead(addr, reg, 3);
return i2c_buffer;
}
bool I2cWrite(uint8_t addr, uint8_t reg, uint32_t val, uint8_t size)
{
uint8_t x = I2C_RETRY_COUNTER;
do {
Wire.beginTransmission((uint8_t)addr); // start transmission to device
Wire.write(reg); // sends register address to write to
uint8_t bytes = size;
while (bytes--) {
Wire.write((val >> (8 * bytes)) & 0xFF); // write data
}
x--;
} while (Wire.endTransmission(true) != 0 && x != 0); // end transmission
return (x);
}
bool I2cWrite8(uint8_t addr, uint8_t reg, uint16_t val)
{
return I2cWrite(addr, reg, val, 1);
}
bool I2cWrite16(uint8_t addr, uint8_t reg, uint16_t val)
{
return I2cWrite(addr, reg, val, 2);
}
int8_t I2cReadBuffer(uint8_t addr, uint8_t reg, uint8_t *reg_data, uint16_t len)
{
Wire.beginTransmission((uint8_t)addr);
Wire.write((uint8_t)reg);
Wire.endTransmission();
if (len != Wire.requestFrom((uint8_t)addr, (uint8_t)len)) {
return 1;
}
while (len--) {
*reg_data = (uint8_t)Wire.read();
reg_data++;
}
return 0;
}
int8_t I2cWriteBuffer(uint8_t addr, uint8_t reg, uint8_t *reg_data, uint16_t len)
{
Wire.beginTransmission((uint8_t)addr);
Wire.write((uint8_t)reg);
while (len--) {
Wire.write(*reg_data);
reg_data++;
}
Wire.endTransmission();
return 0;
}
void I2cScan(char *devs, unsigned int devs_len)
{
// Return error codes defined in twi.h and core_esp8266_si2c.c
// I2C_OK 0
// I2C_SCL_HELD_LOW 1 = SCL held low by another device, no procedure available to recover
// I2C_SCL_HELD_LOW_AFTER_READ 2 = I2C bus error. SCL held low beyond slave clock stretch time
// I2C_SDA_HELD_LOW 3 = I2C bus error. SDA line held low by slave/another_master after n bits
// I2C_SDA_HELD_LOW_AFTER_INIT 4 = line busy. SDA again held low by another device. 2nd master?
uint8_t error = 0;
uint8_t address = 0;
uint8_t any = 0;
snprintf_P(devs, devs_len, PSTR("{\"" D_CMND_I2CSCAN "\":\"" D_JSON_I2CSCAN_DEVICES_FOUND_AT));
for (address = 1; address <= 127; address++) {
Wire.beginTransmission(address);
error = Wire.endTransmission();
if (0 == error) {
any = 1;
snprintf_P(devs, devs_len, PSTR("%s 0x%02x"), devs, address);
}
else if (error != 2) { // Seems to happen anyway using this scan
any = 2;
snprintf_P(devs, devs_len, PSTR("{\"" D_CMND_I2CSCAN "\":\"Error %d at 0x%02x"), error, address);
break;
}
}
if (any) {
strncat(devs, "\"}", devs_len - strlen(devs) -1);
}
else {
snprintf_P(devs, devs_len, PSTR("{\"" D_CMND_I2CSCAN "\":\"" D_JSON_I2CSCAN_NO_DEVICES_FOUND "\"}"));
}
}
void I2cResetActive(uint32_t addr, uint32_t count = 1)
{
addr &= 0x7F; // Max I2C address is 127
count &= 0x7F; // Max 4 x 32 bits available
while (count-- && (addr < 128)) {
i2c_active[addr / 32] &= ~(1 << (addr % 32));
addr++;
}
// AddLog_P2(LOG_LEVEL_DEBUG, PSTR("I2C: Active %08X,%08X,%08X,%08X"), i2c_active[0], i2c_active[1], i2c_active[2], i2c_active[3]);
}
void I2cSetActive(uint32_t addr, uint32_t count = 1)
{
addr &= 0x7F; // Max I2C address is 127
count &= 0x7F; // Max 4 x 32 bits available
while (count-- && (addr < 128)) {
i2c_active[addr / 32] |= (1 << (addr % 32));
addr++;
}
// AddLog_P2(LOG_LEVEL_DEBUG, PSTR("I2C: Active %08X,%08X,%08X,%08X"), i2c_active[0], i2c_active[1], i2c_active[2], i2c_active[3]);
}
void I2cSetActiveFound(uint32_t addr, const char *types)
{
I2cSetActive(addr);
AddLog_P2(LOG_LEVEL_INFO, S_LOG_I2C_FOUND_AT, types, addr);
}
bool I2cActive(uint32_t addr)
{
addr &= 0x7F; // Max I2C address is 127
if (i2c_active[addr / 32] & (1 << (addr % 32))) {
return true;
}
return false;
}
bool I2cSetDevice(uint32_t addr)
{
addr &= 0x7F; // Max I2C address is 127
if (I2cActive(addr)) {
return false; // If already active report as not present;
}
Wire.beginTransmission((uint8_t)addr);
return (0 == Wire.endTransmission());
}
#endif // USE_I2C
/*********************************************************************************************\
* Syslog
*
* Example:
* AddLog_P2(LOG_LEVEL_DEBUG, PSTR(D_LOG_LOG "Any value %d"), value);
*
\*********************************************************************************************/
void SetSeriallog(uint32_t loglevel)
{
Settings.seriallog_level = loglevel;
seriallog_level = loglevel;
seriallog_timer = 0;
}
void SetSyslog(uint32_t loglevel)
{
Settings.syslog_level = loglevel;
syslog_level = loglevel;
syslog_timer = 0;
}
#ifdef USE_WEBSERVER
void GetLog(uint32_t idx, char** entry_pp, size_t* len_p)
{
char* entry_p = nullptr;
size_t len = 0;
if (idx) {
char* it = web_log;
do {
uint32_t cur_idx = *it;
it++;
size_t tmp = strchrspn(it, '\1');
tmp++; // Skip terminating '\1'
if (cur_idx == idx) { // Found the requested entry
len = tmp;
entry_p = it;
break;
}
it += tmp;
} while (it < web_log + WEB_LOG_SIZE && *it != '\0');
}
*entry_pp = entry_p;
*len_p = len;
}
#endif // USE_WEBSERVER
void Syslog(void)
{
// Destroys log_data
uint32_t current_hash = GetHash(SettingsText(SET_SYSLOG_HOST), strlen(SettingsText(SET_SYSLOG_HOST)));
if (syslog_host_hash != current_hash) {
syslog_host_hash = current_hash;
WiFi.hostByName(SettingsText(SET_SYSLOG_HOST), syslog_host_addr); // If sleep enabled this might result in exception so try to do it once using hash
}
if (PortUdp.beginPacket(syslog_host_addr, Settings.syslog_port)) {
char syslog_preamble[64]; // Hostname + Id
snprintf_P(syslog_preamble, sizeof(syslog_preamble), PSTR("%s ESP-"), my_hostname);
memmove(log_data + strlen(syslog_preamble), log_data, sizeof(log_data) - strlen(syslog_preamble));
log_data[sizeof(log_data) -1] = '\0';
memcpy(log_data, syslog_preamble, strlen(syslog_preamble));
PortUdp_write(log_data, strlen(log_data));
PortUdp.endPacket();
delay(1); // Add time for UDP handling (#5512)
} else {
syslog_level = 0;
syslog_timer = SYSLOG_TIMER;
AddLog_P2(LOG_LEVEL_INFO, PSTR(D_LOG_APPLICATION D_SYSLOG_HOST_NOT_FOUND ". " D_RETRY_IN " %d " D_UNIT_SECOND), SYSLOG_TIMER);
}
}
void AddLog(uint32_t loglevel)
{
char mxtime[10]; // "13:45:21 "
snprintf_P(mxtime, sizeof(mxtime), PSTR("%02d" D_HOUR_MINUTE_SEPARATOR "%02d" D_MINUTE_SECOND_SEPARATOR "%02d "), RtcTime.hour, RtcTime.minute, RtcTime.second);
if (loglevel <= seriallog_level) {
Serial.printf("%s%s\r\n", mxtime, log_data);
}
#ifdef USE_WEBSERVER
if (Settings.webserver && (loglevel <= Settings.weblog_level)) {
// Delimited, zero-terminated buffer of log lines.
// Each entry has this format: [index][log data]['\1']
web_log_index &= 0xFF;
if (!web_log_index) web_log_index++; // Index 0 is not allowed as it is the end of char string
while (web_log_index == web_log[0] || // If log already holds the next index, remove it
strlen(web_log) + strlen(log_data) + 13 > WEB_LOG_SIZE) // 13 = web_log_index + mxtime + '\1' + '\0'
{
char* it = web_log;
it++; // Skip web_log_index
it += strchrspn(it, '\1'); // Skip log line
it++; // Skip delimiting "\1"
memmove(web_log, it, WEB_LOG_SIZE -(it-web_log)); // Move buffer forward to remove oldest log line
}
snprintf_P(web_log, sizeof(web_log), PSTR("%s%c%s%s\1"), web_log, web_log_index++, mxtime, log_data);
web_log_index &= 0xFF;
if (!web_log_index) web_log_index++; // Index 0 is not allowed as it is the end of char string
}
#endif // USE_WEBSERVER
if (Settings.flag.mqtt_enabled && // SetOption3 - Enable MQTT
!global_state.mqtt_down &&
(loglevel <= Settings.mqttlog_level)) { MqttPublishLogging(mxtime); }
if (!global_state.wifi_down &&
(loglevel <= syslog_level)) { Syslog(); }
prepped_loglevel = 0;
}
void AddLog_P(uint32_t loglevel, const char *formatP)
{
snprintf_P(log_data, sizeof(log_data), formatP);
AddLog(loglevel);
}
void AddLog_P(uint32_t loglevel, const char *formatP, const char *formatP2)
{
char message[sizeof(log_data)];
snprintf_P(log_data, sizeof(log_data), formatP);
snprintf_P(message, sizeof(message), formatP2);
strncat(log_data, message, sizeof(log_data) - strlen(log_data) -1);
AddLog(loglevel);
}
void PrepLog_P2(uint32_t loglevel, PGM_P formatP, ...)
{
va_list arg;
va_start(arg, formatP);
vsnprintf_P(log_data, sizeof(log_data), formatP, arg);
va_end(arg);
prepped_loglevel = loglevel;
}
void AddLog_P2(uint32_t loglevel, PGM_P formatP, ...)
{
va_list arg;
va_start(arg, formatP);
vsnprintf_P(log_data, sizeof(log_data), formatP, arg);
va_end(arg);
AddLog(loglevel);
}
void AddLog_Debug(PGM_P formatP, ...)
{
va_list arg;
va_start(arg, formatP);
vsnprintf_P(log_data, sizeof(log_data), formatP, arg);
va_end(arg);
AddLog(LOG_LEVEL_DEBUG);
}
void AddLogBuffer(uint32_t loglevel, uint8_t *buffer, uint32_t count)
{
/*
snprintf_P(log_data, sizeof(log_data), PSTR("DMP:"));
for (uint32_t i = 0; i < count; i++) {
snprintf_P(log_data, sizeof(log_data), PSTR("%s %02X"), log_data, *(buffer++));
}
AddLog(loglevel);
*/
/*
strcpy_P(log_data, PSTR("DMP: "));
ToHex_P(buffer, count, log_data + strlen(log_data), sizeof(log_data) - strlen(log_data), ' ');
AddLog(loglevel);
*/
char hex_char[(count * 3) + 2];
AddLog_P2(loglevel, PSTR("DMP: %s"), ToHex_P(buffer, count, hex_char, sizeof(hex_char), ' '));
}
void AddLogSerial(uint32_t loglevel)
{
AddLogBuffer(loglevel, (uint8_t*)serial_in_buffer, serial_in_byte_counter);
}
void AddLogMissed(const char *sensor, uint32_t misses)
{
AddLog_P2(LOG_LEVEL_DEBUG, PSTR("SNS: %s missed %d"), sensor, SENSOR_MAX_MISS - misses);
}