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utils.cpp
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utils.cpp
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// General utilities not specific to this app to support:
// - wifi
// - NTP
// - remote logging
// - base64 encoding
// - device sleep
//
// s60sc 2021, 2023
// some functions based on code contributed by gemi254
#include "appGlobals.h"
bool dbgVerbose = false;
bool timeSynchronized = false;
bool monitorOpen = true;
bool dataFilesChecked = false;
// allow any startup failures to be reported via browser for remote devices
char startupFailure[SF_LEN] = {0};
size_t alertBufferSize = 0;
byte* alertBuffer = NULL; // buffer for telegram / smtp alert image
RTC_NOINIT_ATTR uint32_t crashLoop;
RTC_NOINIT_ATTR char brownoutStatus;
static void initBrownout(void);
int wakePin; // if wakeUse is true
bool wakeUse = false; // true to allow app to sleep and wake
/************************** Wifi **************************/
#include <esp_task_wdt.h>
/** Do not hard code anything below here unless you know what you are doing **/
/** Use the web interface to configure wifi settings **/
char hostName[MAX_HOST_LEN] = ""; // Default Host name
char ST_SSID[MAX_HOST_LEN] = ""; //Default router ssid
char ST_Pass[MAX_PWD_LEN] = ""; //Default router passd
// leave following blank for dhcp
char ST_ip[MAX_IP_LEN] = ""; // Static IP
char ST_sn[MAX_IP_LEN] = ""; // subnet normally 255.255.255.0
char ST_gw[MAX_IP_LEN] = ""; // gateway to internet, normally router IP
char ST_ns1[MAX_IP_LEN] = ""; // DNS Server, can be router IP (needed for SNTP)
char ST_ns2[MAX_IP_LEN] = ""; // alternative DNS Server, can be blank
// Access point Config Portal SSID and Pass
char AP_SSID[MAX_HOST_LEN] = "";
char AP_Pass[MAX_PWD_LEN] = "";
char AP_ip[MAX_IP_LEN] = ""; // Leave blank to use 192.168.4.1
char AP_sn[MAX_IP_LEN] = "";
char AP_gw[MAX_IP_LEN] = "";
// basic HTTP Authentication access to web page
char Auth_Name[MAX_HOST_LEN] = "";
char Auth_Pass[MAX_PWD_LEN] = "";
int responseTimeoutSecs = 10; // time to wait for FTP or SMTP response
bool allowAP = true; // set to true to allow AP to startup if cannot connect to STA (router)
uint32_t wifiTimeoutSecs = 30; // how often to check wifi status
static bool APstarted = false;
esp_ping_handle_t pingHandle = NULL;
bool usePing = true;
static void startPing();
static void setupMdnsHost() {
// set up MDNS service
char mdnsName[MAX_IP_LEN]; // max mdns host name length
snprintf(mdnsName, MAX_IP_LEN, "%.*s", MAX_IP_LEN - 1, hostName);
if (MDNS.begin(mdnsName)) {
// Add service to MDNS
MDNS.addService("http", "tcp", HTTP_PORT);
MDNS.addService("https", "tcp", HTTPS_PORT);
//MDNS.addService("ws", "udp", 83);
//MDNS.addService("ftp", "tcp", 21);
LOG_INF("mDNS service: http://%s.local", mdnsName);
} else LOG_WRN("mDNS host: %s Failed", mdnsName);
debugMemory("setupMdnsHost");
}
static const char* wifiStatusStr(wl_status_t wlStat) {
switch (wlStat) {
case WL_NO_SHIELD: return "wifi not initialised";
case WL_IDLE_STATUS: return "WL_IDLE_STATUS";
case WL_NO_SSID_AVAIL: return "not available, use AP";
case WL_SCAN_COMPLETED: return "WL_SCAN_COMPLETED";
case WL_CONNECTED: return "WL_CONNECTED";
case WL_CONNECT_FAILED: return "WL_CONNECT_FAILED";
case WL_CONNECTION_LOST: return "WL_CONNECTION_LOST";
case WL_DISCONNECTED: return "unable to connect";
case WL_STOPPED: return "wifi stopped";
default: return "Invalid WiFi.status";
}
}
const char* getEncType(int ssidIndex) {
switch (WiFi.encryptionType(ssidIndex)) {
case (WIFI_AUTH_OPEN): return "Open";
case (WIFI_AUTH_WEP): return "WEP";
case (WIFI_AUTH_WPA_PSK): return "WPA_PSK";
case (WIFI_AUTH_WPA2_PSK): return "WPA2_PSK";
case (WIFI_AUTH_WPA_WPA2_PSK): return "WPA_WPA2_PSK";
case (WIFI_AUTH_WPA2_ENTERPRISE): return "WPA2_ENTERPRISE";
case (WIFI_AUTH_MAX): return "AUTH_MAX";
default: return "Not listed";
}
}
static void onWiFiEvent(WiFiEvent_t event) {
// callback to report on wifi events
switch (event) {
case ARDUINO_EVENT_WIFI_READY: break;
case ARDUINO_EVENT_WIFI_SCAN_DONE: break;
case ARDUINO_EVENT_WIFI_STA_START: LOG_INF("Wifi Station started, connecting to: %s", ST_SSID); break;
case ARDUINO_EVENT_WIFI_STA_STOP: LOG_INF("Wifi Station stopped %s", ST_SSID); break;
case ARDUINO_EVENT_WIFI_AP_START: {
if (strlen(AP_SSID) && !strcmp(WiFi.softAPSSID().c_str(), AP_SSID)) {
LOG_INF("Wifi AP SSID: %s started, use '%s://%s' to connect", WiFi.softAPSSID().c_str(), useHttps ? "https" : "http", WiFi.softAPIP().toString().c_str());
APstarted = true;
}
break;
}
case ARDUINO_EVENT_WIFI_AP_STOP: {
if (!strcmp(WiFi.softAPSSID().c_str(), AP_SSID)) {
LOG_INF("Wifi AP stopped: %s", AP_SSID);
APstarted = false;
}
break;
}
case ARDUINO_EVENT_WIFI_STA_GOT_IP: LOG_INF("Wifi Station IP, use '%s://%s' to connect", useHttps ? "https" : "http", WiFi.localIP().toString().c_str()); break;
case ARDUINO_EVENT_WIFI_STA_LOST_IP: LOG_INF("Wifi Station lost IP"); break;
case ARDUINO_EVENT_WIFI_AP_STAIPASSIGNED: break;
case ARDUINO_EVENT_WIFI_STA_CONNECTED: LOG_INF("WiFi Station connection to %s, using hostname: %s", ST_SSID, hostName); break;
case ARDUINO_EVENT_WIFI_STA_DISCONNECTED: LOG_INF("WiFi Station disconnected"); break;
case ARDUINO_EVENT_WIFI_AP_STACONNECTED: LOG_INF("WiFi AP client connection"); break;
case ARDUINO_EVENT_WIFI_AP_STADISCONNECTED: LOG_INF("WiFi AP client disconnection"); break;
case ARDUINO_EVENT_WIFI_AP_PROBEREQRECVED: break;
case ARDUINO_EVENT_WIFI_AP_GOT_IP6: LOG_INF("AP interface V6 IP addr is preferred"); break;
case ARDUINO_EVENT_WIFI_STA_GOT_IP6: LOG_INF("Station interface V6 IP addr is preferred"); break;
default: LOG_WRN("WiFi Unhandled event %d", event); break;
}
}
static void setWifiAP() {
if (!APstarted) {
// Set access point with static ip if provided
if (strlen(AP_ip) > 1) {
LOG_INF("Set AP static IP :%s, %s, %s", AP_ip, AP_gw, AP_sn);
IPAddress _ip, _gw, _sn, _ns1 ,_ns2;
_ip.fromString(AP_ip);
_gw.fromString(AP_gw);
_sn.fromString(AP_sn);
// set static ip
WiFi.softAPConfig(_ip, _gw, _sn);
}
WiFi.softAP(AP_SSID, AP_Pass);
debugMemory("setWifiAP");
}
}
static void setWifiSTA() {
// set station with static ip if provided
if (strlen(ST_ip) > 1) {
IPAddress _ip, _gw, _sn, _ns1, _ns2;
if (!_ip.fromString(ST_ip)) LOG_WRN("Failed to parse IP: %s", ST_ip);
else {
_ip.fromString(ST_ip);
_gw.fromString(ST_gw);
_sn.fromString(ST_sn);
_ns1.fromString(ST_ns1);
_ns2.fromString(ST_ns2);
// set static ip
WiFi.config(_ip, _gw, _sn, _ns1); // need DNS for SNTP
LOG_INF("Wifi Station set static IP");
}
} else LOG_INF("Wifi Station IP from DHCP");
WiFi.enableIPv6(USE_IP6);
WiFi.begin(ST_SSID, ST_Pass);
debugMemory("setWifiSTA");
}
bool startWifi(bool firstcall) {
// start wifi station (and wifi AP if allowed or station not defined)
if (firstcall) {
WiFi.mode(WIFI_AP_STA);
WiFi.persistent(false); // prevent the flash storage WiFi credentials
WiFi.setAutoReconnect(false); // Set whether module will attempt to reconnect to an access point in case it is disconnected
WiFi.softAPdisconnect(true); // kill rogue AP on startup
WiFi.setHostname(hostName);
delay(100);
WiFi.onEvent(onWiFiEvent);
}
setWifiSTA();
// connect to Wifi station
uint32_t startAttemptTime = millis();
// Stop trying on failure timeout, will try to reconnect later by ping
wl_status_t wlStat = WL_NO_SSID_AVAIL;
if (strlen(ST_SSID)) {
while (wlStat = WiFi.status(), wlStat != WL_CONNECTED && millis() - startAttemptTime < 5000) {
logPrint(".");
delay(500);
}
}
if (wlStat == WL_NO_SSID_AVAIL || allowAP) setWifiAP(); // AP allowed if no Station SSID eg on first time use
if (wlStat != WL_CONNECTED) LOG_WRN("SSID %s not connected %s", ST_SSID, wifiStatusStr(wlStat));
#if CONFIG_IDF_TARGET_ESP32S3
setupMdnsHost(); // not on ESP32 as uses 6k of heap
#endif
// show stats of requested SSID
int numNetworks = WiFi.scanNetworks();
for (int i=0; i < numNetworks; i++) {
if (!strcmp(WiFi.SSID(i).c_str(), ST_SSID))
LOG_INF("Wifi stats for %s - signal strength: %d dBm; Encryption: %s; channel: %u", ST_SSID, WiFi.RSSI(i), getEncType(i), WiFi.channel(i));
}
if (pingHandle == NULL) startPing();
return wlStat == WL_CONNECTED ? true : false;
}
void resetWatchDog() {
// use ping task as watchdog in case of freeze
static bool watchDogStarted = false;
if (watchDogStarted) esp_task_wdt_reset();
else {
esp_task_wdt_deinit();
esp_task_wdt_config_t twdt_config = {
.timeout_ms = (wifiTimeoutSecs * 1000 * 2),
.idle_core_mask = (1 << portNUM_PROCESSORS) - 1,
.trigger_panic = true, // panic abort on watchdog alert (contains wdt_isr)
};
esp_task_wdt_init(&twdt_config);
esp_task_wdt_add(NULL);
if (esp_task_wdt_status(NULL) == ESP_OK) {
watchDogStarted = true;
esp_task_wdt_reset();
LOG_INF("WatchDog started using task: %s", pcTaskGetName(NULL));
} else LOG_ERR("WatchDog failed to start");
}
}
static void statusCheck() {
// regular status checks
doAppPing();
if (!timeSynchronized) getLocalNTP();
if (!dataFilesChecked) dataFilesChecked = checkDataFiles();
#if INCLUDE_MQTT
if (mqtt_active) startMqttClient();
#endif
}
void resetCrashLoop() {
crashLoop = 0;
}
static void pingSuccess(esp_ping_handle_t hdl, void *args) {
//uint32_t elapsed_time;
//esp_ping_get_profile(hdl, ESP_PING_PROF_TIMEGAP, &elapsed_time, sizeof(elapsed_time));
if (DEBUG_MEM) {
static uint32_t minStack = UINT32_MAX;
uint32_t freeStack = (uint32_t)uxTaskGetStackHighWaterMark(NULL);
if (freeStack < minStack) {
minStack = freeStack;
if (freeStack < MIN_STACK_FREE) LOG_WRN("Task ping stack space only: %u", freeStack);
else LOG_INF("Task ping stack space reduced to: %u", freeStack);
}
}
resetWatchDog();
if (dataFilesChecked) resetCrashLoop();
statusCheck();
}
static void pingTimeout(esp_ping_handle_t hdl, void *args) {
// a ping check is used because esp may maintain a connection to gateway which may be unuseable, which is detected by ping failure
// but some routers may not respond to ping - https://github.com/s60sc/ESP32-CAM_MJPEG2SD/issues/221
// so setting usePing to false ignores ping failure if connection still present
resetWatchDog();
if (strlen(ST_SSID)) {
wl_status_t wStat = WiFi.status();
if (wStat != WL_NO_SSID_AVAIL && wStat != WL_NO_SHIELD) {
if (usePing) {
LOG_WRN("Failed to ping gateway, restart wifi ...");
startWifi(false);
} else {
if (wStat == WL_CONNECTED) statusCheck(); // treat as ok
else {
LOG_WRN("Disconnected, restart wifi ...");
startWifi(false);
}
}
}
}
}
static void startPing() {
IPAddress ipAddr = WiFi.gatewayIP();
ip_addr_t pingDest;
IP_ADDR4(&pingDest, ipAddr[0], ipAddr[1], ipAddr[2], ipAddr[3]);
esp_ping_config_t pingConfig = ESP_PING_DEFAULT_CONFIG();
pingConfig.target_addr = pingDest;
pingConfig.count = ESP_PING_COUNT_INFINITE;
pingConfig.interval_ms = wifiTimeoutSecs * 1000;
pingConfig.timeout_ms = 5000;
pingConfig.task_stack_size = PING_STACK_SIZE;
pingConfig.task_prio = 1;
// set ping task callback functions
esp_ping_callbacks_t cbs;
cbs.on_ping_success = pingSuccess;
cbs.on_ping_timeout = pingTimeout;
cbs.on_ping_end = NULL;
cbs.cb_args = NULL;
esp_ping_new_session(&pingConfig, &cbs, &pingHandle);
esp_ping_start(pingHandle);
LOG_INF("Started ping monitoring - %s", usePing ? "On" : "Off");
debugMemory("startPing");
}
void stopPing() {
if (pingHandle != NULL) {
esp_ping_stop(pingHandle);
esp_ping_delete_session(pingHandle);
pingHandle = NULL;
}
}
#define EXT_IP_HOST "api.ipify.org"
char extIP[MAX_IP_LEN] = "Not assigned"; // router external IP
bool doGetExtIP = true;
void getExtIP() {
// Get external IP address
if (doGetExtIP) {
NetworkClientSecure hclient;
if (remoteServerConnect(hclient, EXT_IP_HOST, HTTPS_PORT, "", GETEXTIP)) {
HTTPClient https;
int httpCode = HTTP_CODE_NOT_FOUND;
if (https.begin(hclient, EXT_IP_HOST, HTTPS_PORT, "/", true)) {
char newExtIp[MAX_IP_LEN] = "";
httpCode = https.GET();
if (httpCode == HTTP_CODE_OK) {
strncpy(newExtIp, https.getString().c_str(), sizeof(newExtIp) - 1);
if (strcmp(newExtIp, extIP)) {
// external IP changed
strncpy(extIP, newExtIp, sizeof(extIP) - 1);
updateStatus("extIP", extIP);
updateStatus("save", "0");
externalAlert("External IP changed", extIP);
} else LOG_INF("External IP: %s", extIP);
} else LOG_WRN("External IP request failed, error: %s", https.errorToString(httpCode).c_str());
if (httpCode != HTTP_CODE_OK) doGetExtIP = false;
https.end();
}
remoteServerClose(hclient);
}
}
}
/************** generic NetworkClientSecure functions ******************/
static uint8_t failCounts[REMFAILCNT] = {0};
void remoteServerClose(NetworkClientSecure& sclient) {
if (sclient.available()) sclient.clear();
if (sclient.connected()) sclient.stop();
}
bool remoteServerConnect(NetworkClientSecure& sclient, const char* serverName, uint16_t serverPort, const char* serverCert, uint8_t connIdx) {
// Connect to server if not already connected or previously disconnected
if (sclient.connected()) return true;
else {
if (failCounts[connIdx] >= MAX_FAIL) {
if (failCounts[connIdx] == MAX_FAIL) {
LOG_ERR("Abandon %s connection attempt until next rollover", serverName);
failCounts[connIdx] = MAX_FAIL + 1;
}
} else {
if (ESP.getFreeHeap() > TLS_HEAP) {
// not connected, so try for a period of time
if (useSecure && strlen(serverCert)) sclient.setCACert(serverCert);
else sclient.setInsecure(); // no cert check
uint32_t startTime = millis();
while (!sclient.connected()) {
if (sclient.connect(serverName, serverPort)) break;
if (millis() - startTime > responseTimeoutSecs * 1000) break;
delay(2000);
}
if (sclient.connected()) {
failCounts[connIdx] = 0;
return true;
}
else {
// failed to connect in allocated time
// 'Memory allocation failed' indicates lack of heap space
// 'Generic error' can indicate DNS failure
char errBuf[100] = "Unknown server error";
int errNum = sclient.lastError(errBuf, sizeof(errBuf));
LOG_WRN("Timed out connecting to server: %s, Err: %d, %s", serverName, errNum, errBuf);
}
} else LOG_WRN("Insufficient heap %s for %s TLS session", fmtSize(ESP.getFreeHeap()), serverName);
failCounts[connIdx]++;
}
}
return false;
}
void remoteServerReset() {
// reset fail counts
for (uint8_t i = 0; i < REMFAILCNT; i++) failCounts[i] = 0;
}
/************************** NTP **************************/
// Needs to be a time zone string from: https://raw.githubusercontent.com/nayarsystems/posix_tz_db/master/zones.csv
char timezone[FILE_NAME_LEN] = "GMT0";
char ntpServer[MAX_HOST_LEN] = "pool.ntp.org";
uint8_t alarmHour = 1;
time_t getEpoch() {
struct timeval tv;
gettimeofday(&tv, NULL);
return tv.tv_sec;
}
void dateFormat(char* inBuff, size_t inBuffLen, bool isFolder) {
// construct filename from date/time
time_t currEpoch = getEpoch();
if (isFolder) strftime(inBuff, inBuffLen, "/%Y%m%d", localtime(&currEpoch));
else strftime(inBuff, inBuffLen, "/%Y%m%d/%Y%m%d_%H%M%S", localtime(&currEpoch));
}
static void showLocalTime(const char* timeSrc) {
time_t currEpoch = getEpoch();
char timeFormat[20];
strftime(timeFormat, sizeof(timeFormat), "%d/%m/%Y %H:%M:%S", localtime(&currEpoch));
LOG_INF("Got current time from %s: %s with tz: %s", timeSrc, timeFormat, timezone);
timeSynchronized = true;
}
bool getLocalNTP() {
// get current time from NTP server and apply to ESP32
LOG_INF("Using NTP server: %s", ntpServer);
configTzTime(timezone, ntpServer);
if (getEpoch() > 10000) {
showLocalTime("NTP");
return true;
}
else {
LOG_WRN("Not yet synced with NTP");
return false;
}
}
void syncToBrowser(uint32_t browserUTC) {
// Synchronize to browser clock if out of sync
if (!timeSynchronized) {
struct timeval tv;
tv.tv_sec = browserUTC;
settimeofday(&tv, NULL);
setenv("TZ", timezone, 1);
tzset();
showLocalTime("browser");
}
}
void formatElapsedTime(char* timeStr, uint32_t timeVal, bool noDays) {
// elapsed time that app has been running
uint32_t secs = timeVal / 1000; //convert milliseconds to seconds
uint32_t mins = secs / 60; //convert seconds to minutes
uint32_t hours = mins / 60; //convert minutes to hours
uint32_t days = hours / 24; //convert hours to days
secs = secs - (mins * 60); //subtract the converted seconds to minutes in order to display 59 secs max
mins = mins - (hours * 60); //subtract the converted minutes to hours in order to display 59 minutes max
hours = hours - (days * 24); //subtract the converted hours to days in order to display 23 hours max
if (noDays) sprintf(timeStr, "%02lu:%02lu:%02lu", hours, mins, secs);
else sprintf(timeStr, "%lu-%02lu:%02lu:%02lu", days, hours, mins, secs);
}
static time_t setAlarm(uint8_t alarmHour) {
// calculate future alarm datetime based on current datetime
// ensure relevant timezone identified (default GMT0)
time_t currEpoch = getEpoch();
struct tm* timeinfo = localtime(&currEpoch);
// set alarm date & time for next given hour
int nextDay = 0; // try same day then next day
do {
timeinfo->tm_mday += nextDay;
timeinfo->tm_hour = alarmHour;
timeinfo->tm_min = 0;
timeinfo->tm_sec = 0;
nextDay = 1;
} while (mktime(timeinfo) < getEpoch());
char inBuff[30];
strftime(inBuff, sizeof(inBuff), "%d/%m/%Y %H:%M:%S", timeinfo);
LOG_INF("Alarm scheduled at %s", inBuff);
// return future alarm time as epoch seconds
return mktime(timeinfo);
}
bool checkAlarm() {
// call from appPing() to check if daily alarm time at given hour has occurred
static time_t rolloverEpoch = 0;
if (timeSynchronized && getEpoch() >= rolloverEpoch) {
// alarm time reached
rolloverEpoch = setAlarm(alarmHour); // set next alarm time
return true;
}
return false;
}
/********************** misc functions ************************/
bool changeExtension(char* fileName, const char* newExt) {
// replace original file extension with supplied extension (buffer must be large enough)
size_t inNamePtr = strlen(fileName);
// find '.' before extension text
while (inNamePtr > 0 && fileName[inNamePtr] != '.') inNamePtr--;
inNamePtr++;
size_t extLen = strlen(newExt);
memcpy(fileName + inNamePtr, newExt, extLen);
fileName[inNamePtr + extLen] = 0;
return (inNamePtr > 1) ? true : false;
}
void showProgress(const char* marker) {
// show progess as dots
static uint8_t dotCnt = 0;
logPrint(marker); // progress marker
if (++dotCnt >= DOT_MAX) {
dotCnt = 0;
logLine();
}
}
bool calcProgress(int progressVal, int totalVal, int percentReport, uint8_t &pcProgress) {
// calculate percentage progress, only report back on percentReport boundary
uint8_t percentage = (progressVal * 100) / totalVal;
if (percentage >= pcProgress + percentReport) {
pcProgress = percentage;
return true;
} else return false;
}
bool urlEncode(const char* inVal, char* encoded, size_t maxSize) {
int encodedLen = 0;
char hexTable[] = "0123456789ABCDEF";
while (*inVal) {
if (isalnum(*inVal) || strchr("$-_.+!*'(),:@~#", *inVal)) *encoded++ = *inVal;
else {
encodedLen += 3;
if (encodedLen >= maxSize) return false; // Buffer overflow
*encoded++ = '%';
*encoded++ = hexTable[(*inVal) >> 4];
*encoded++ = hexTable[*inVal & 0xf];
}
inVal++;
}
*encoded = 0;
return true;
}
void urlDecode(char* inVal) {
// replace url encoded characters
std::string decodeVal(inVal);
std::string replaceVal = decodeVal;
std::smatch match;
while (regex_search(decodeVal, match, std::regex("(%)([0-9A-Fa-f]{2})"))) {
std::string s(1, static_cast<char>(std::strtoul(match.str(2).c_str(),nullptr,16))); // hex to ascii
replaceVal = std::regex_replace(replaceVal, std::regex(match.str(0)), s);
decodeVal = match.suffix().str();
}
strcpy(inVal, replaceVal.c_str());
}
void listBuff (const uint8_t* b, size_t len) {
// output buffer content as hex, 16 bytes per line
if (!len || !b) LOG_WRN("Nothing to print");
else {
for (size_t i = 0; i < len; i += 16) {
int linelen = (len - i) < 16 ? (len - i) : 16;
for (size_t k = 0; k < linelen; k++) logPrint(" %02x", b[i+k]);
puts(" ");
}
}
}
size_t isSubArray(uint8_t* haystack, uint8_t* needle, size_t hSize, size_t nSize) {
// find a subarray (needle) in another array (haystack)
size_t h = 0, n = 0; // Two pointers to traverse the arrays
// Traverse both arrays simultaneously
while (h < hSize && n < nSize) {
// If element matches, increment both pointers
if (haystack[h] == needle[n]) {
h++;
n++;
// If needle is completely traversed
if (n == nSize) return h; // position of end of needle
} else {
// if not, increment h and reset n
h = h - n + 1;
n = 0;
}
}
return 0; // not found
}
void removeChar(char* s, char c) {
// remove specified character from string
int writer = 0, reader = 0;
while (s[reader]) {
if (s[reader] != c) s[writer++] = s[reader];
reader++;
}
s[writer] = 0;
}
void replaceChar(char* s, char c, char r) {
// replace specified character in string
int reader = 0;
while (s[reader]) {
if (s[reader] == c) s[reader] = r;
reader++;
}
}
char* fmtSize (uint64_t sizeVal) {
// format size according to magnitude
// only one call per format string
static char returnStr[20];
if (sizeVal < 50 * 1024) sprintf(returnStr, "%llu bytes", sizeVal);
else if (sizeVal < ONEMEG) sprintf(returnStr, "%lluKB", sizeVal / 1024);
else if (sizeVal < ONEMEG * 1024) sprintf(returnStr, "%0.1fMB", (double)(sizeVal) / ONEMEG);
else sprintf(returnStr, "%0.1fGB", (double)(sizeVal) / (ONEMEG * 1024));
return returnStr;
}
void checkMemory(const char* source ) {
LOG_INF("%s Free: heap %u, block: %u, min: %u, pSRAM %u", source, ESP.getFreeHeap(), ESP.getMaxAllocHeap(), ESP.getMinFreeHeap(), ESP.getFreePsram());
if (ESP.getFreeHeap() < WARN_HEAP) LOG_WRN("Free heap only %u, min %u", ESP.getFreeHeap(), ESP.getMinFreeHeap());
if (ESP.getMaxAllocHeap() < WARN_ALLOC) LOG_WRN("Max allocatable heap block is only %u", ESP.getMaxAllocHeap());
}
uint32_t checkStackUse(TaskHandle_t thisTask, int taskIdx) {
// get minimum free stack size for task since started
static uint32_t minStack[20];
uint32_t freeStack = 0;
if (thisTask != NULL) {
freeStack = (uint32_t)uxTaskGetStackHighWaterMark(thisTask);
if (!minStack[taskIdx]) {
minStack[taskIdx] = freeStack; // initialise
LOG_INF("Task %s on core %d, initial stack space %u", pcTaskGetTaskName(thisTask), xPortGetCoreID(), freeStack);
}
if (freeStack < minStack[taskIdx]) {
minStack[taskIdx] = freeStack;
if (freeStack < MIN_STACK_FREE) LOG_WRN("Task %s on core %d, stack space only: %u", pcTaskGetTaskName(thisTask), xPortGetCoreID(), freeStack);
else LOG_INF("Task %s on core %d, stack space reduced to %u", pcTaskGetTaskName(thisTask), xPortGetCoreID(), freeStack);
}
}
return freeStack;
}
void debugMemory(const char* caller) {
if (DEBUG_MEM) {
logPrint("%s > Free: heap %u, block: %u, min: %u, pSRAM %u\n", caller, ESP.getFreeHeap(), ESP.getMaxAllocHeap(), ESP.getMinFreeHeap(), ESP.getFreePsram());
delay(FLUSH_DELAY);
}
}
void doRestart(const char* restartStr) {
LOG_ALT("Controlled restart: %s", restartStr);
#ifdef ISCAM
appShutdown();
#endif
#if INCLUDE_MQTT
if (mqtt_active) stopMqttClient();
#endif
resetCrashLoop();
flush_log(true);
delay(2000);
ESP.restart();
}
uint16_t smoothAnalog(int analogPin, int samples) {
// get averaged analog pin value
uint32_t level = 0;
if (analogPin > 0) {
for (int j = 0; j < samples; j++) level += analogRead(analogPin);
level /= samples;
}
return level;
}
void setupADC() {
analogSetAttenuation(ADC_ATTEN);
analogReadResolution(ADC_BITS);
}
float smoothSensor(float latestVal, float smoothedVal, float alpha) {
// simple Exponential Moving Average filter
// where alpha between 0.0 (max smooth) and 1.0 (no smooth)
return (latestVal * alpha) + smoothedVal * (1.0 - alpha);
}
// onboard chip temperature sensor
#if CONFIG_IDF_TARGET_ESP32
extern "C" {
// Use internal on chip temperature sensor (if present)
uint8_t temprature_sens_read(); // sic
}
#elif CONFIG_IDF_TARGET_ESP32S3 || CONFIG_IDF_TARGET_ESP32C3
#include "driver/temperature_sensor.h"
static temperature_sensor_handle_t temp_sensor = NULL;
#endif
static void prepInternalTemp() {
#if CONFIG_IDF_TARGET_ESP32S2 || CONFIG_IDF_TARGET_ESP32C3 || CONFIG_IDF_TARGET_ESP32S3
// setup internal sensor
temperature_sensor_config_t temp_sensor_config = TEMPERATURE_SENSOR_CONFIG_DEFAULT(20, 100);
temperature_sensor_install(&temp_sensor_config, &temp_sensor);
temperature_sensor_enable(temp_sensor);
#endif
}
float readInternalTemp() {
float intTemp = NULL_TEMP;
#if CONFIG_IDF_TARGET_ESP32
// convert on chip raw temperature in F to Celsius degrees
intTemp = (temprature_sens_read() - 32) / 1.8; // value of 55 means not present
#elif CONFIG_IDF_TARGET_ESP32S2 || CONFIG_IDF_TARGET_ESP32C3 || CONFIG_IDF_TARGET_ESP32S3
temperature_sensor_get_celsius(temp_sensor, &intTemp);
#endif
return intTemp;
}
/*********************** Remote loggging ***********************/
/*
* Log mode selection in user interface:
* false : log to serial / web monitor only
* true : also saves log on SD card. To download the log generated, either:
* - To view the log, press Show Log button on the browser
* - To clear the log file contents, on log web page press Clear Log link
*/
#define MAX_OUT 200
static va_list arglist;
static char fmtBuf[MAX_OUT];
static char outBuf[MAX_OUT];
char alertMsg[MAX_OUT];
TaskHandle_t logHandle = NULL;
static SemaphoreHandle_t logSemaphore = NULL;
static SemaphoreHandle_t logMutex = NULL;
static int logWait = 100; // ms
bool useLogColors = false; // true to colorise log messages (eg if using idf.py, but not arduino)
bool wsLog = false;
#define WRITE_CACHE_CYCLE 5
bool sdLog = false; // log to SD
int logType = 0; // which log contents to display (0 : ram, 1 : sd, 2 : ws)
static FILE* log_remote_fp = NULL;
static uint32_t counter_write = 0;
// RAM memory based logging in RTC slow memory (cannot init)
RTC_NOINIT_ATTR char messageLog[RAM_LOG_LEN];
RTC_NOINIT_ATTR uint16_t mlogEnd;
static void ramLogClear() {
mlogEnd = 0;
memset(messageLog, 0, RAM_LOG_LEN);
}
static void ramLogStore(size_t msgLen) {
// save log entry in ram buffer
if (mlogEnd + msgLen >= RAM_LOG_LEN) {
// log needs to roll around cyclic buffer
uint16_t firstPart = RAM_LOG_LEN - mlogEnd;
memcpy(messageLog + mlogEnd, outBuf, firstPart);
msgLen -= firstPart;
memcpy(messageLog, outBuf + firstPart, msgLen);
mlogEnd = 0;
} else memcpy(messageLog + mlogEnd, outBuf, msgLen);
mlogEnd += msgLen;
}
void flush_log(bool andClose) {
if (log_remote_fp != NULL) {
fsync(fileno(log_remote_fp));
fflush(log_remote_fp);
if (andClose) {
LOG_INF("Closed SD file for logging");
fclose(log_remote_fp);
log_remote_fp = NULL;
} else delay(1000);
}
}
static void remote_log_init_SD() {
#if !CONFIG_IDF_TARGET_ESP32C3
STORAGE.mkdir(DATA_DIR);
// Open remote file
log_remote_fp = NULL;
log_remote_fp = fopen("/sdcard" LOG_FILE_PATH, "a");
if (log_remote_fp == NULL) {LOG_WRN("Failed to open SD log file %s", LOG_FILE_PATH);}
else {
logPrint(" \n");
LOG_INF("Opened SD file for logging");
}
#endif
}
void reset_log() {
if (logType == 0) ramLogClear();
if (logType == 2) {
if (log_remote_fp != NULL) flush_log(true); // Close log file
STORAGE.remove(LOG_FILE_PATH);
remote_log_init_SD();
}
if (logType != 1) LOG_INF("Cleared %s log file", logType == 0 ? "RAM" : "SD");
}
void remote_log_init() {
// setup required log mode
if (sdLog) {
flush_log(false);
remote_log_init_SD(); // store log on sd card
} else flush_log(true);
}
static void logTask(void *arg) {
// separate task to reduce stack size in other tasks
while(true) {
ulTaskNotifyTake(pdTRUE, portMAX_DELAY);
vsnprintf(outBuf, MAX_OUT, fmtBuf, arglist);
va_end(arglist);
xSemaphoreGive(logSemaphore);
}
}
void logPrint(const char *format, ...) {
// feeds logTask to format message, then outputs as required
if (xSemaphoreTake(logMutex, pdMS_TO_TICKS(logWait)) == pdTRUE) {
strncpy(fmtBuf, format, MAX_OUT);
va_start(arglist, format);
vTaskPrioritySet(logHandle, uxTaskPriorityGet(NULL) + 1);
xTaskNotifyGive(logHandle);
outBuf[MAX_OUT - 2] = '\n';
outBuf[MAX_OUT - 1] = 0; // ensure always have ending newline
xSemaphoreTake(logSemaphore, portMAX_DELAY); // wait for logTask to complete
// output to monitor console if attached
size_t msgLen = strlen(outBuf);
if (outBuf[msgLen - 2] == '~') {
// set up alert message for browser
outBuf[msgLen - 2] = ' ';
strncpy(alertMsg, outBuf, MAX_OUT - 1);
alertMsg[msgLen - 2] = 0;
}
ramLogStore(msgLen); // store in rtc ram
if (monitorOpen) Serial.print(outBuf);
else delay(10); // allow time for other tasks
if (sdLog) {
if (log_remote_fp != NULL) {
// output to SD if file opened
fwrite(outBuf, sizeof(char), msgLen, log_remote_fp); // log.txt
// periodic sync to SD
if (counter_write++ % WRITE_CACHE_CYCLE == 0) fsync(fileno(log_remote_fp));
}
}
// output to web socket if open
if (msgLen > 1) {
outBuf[msgLen - 1] = 0; // lose final '/n'
if (wsLog) wsAsyncSendText(outBuf);
}
xSemaphoreGive(logMutex);
}
}
void logLine() {
logPrint(" \n");
}
void logSetup() {
// prep logging environment
Serial.begin(115200);
Serial.setDebugOutput(DBG_ON);
printf("\n\n");
if (DEBUG_MEM) printf("init > Free: heap %lu\n", ESP.getFreeHeap());
if (!DBG_ON) esp_log_level_set("*", ESP_LOG_NONE); // suppress ESP_LOG_ERROR messages
if (crashLoop == MAGIC_NUM) snprintf(startupFailure, SF_LEN, STARTUP_FAIL "Crash loop detected, check log %s", (brownoutStatus == 'B' || brownoutStatus == 'R') ? "(brownout)" : " ");
crashLoop = MAGIC_NUM;
logSemaphore = xSemaphoreCreateBinary(); // flag that log message formatted
logMutex = xSemaphoreCreateMutex(); // control access to log formatter
xSemaphoreGive(logSemaphore);
xSemaphoreGive(logMutex);
xTaskCreate(logTask, "logTask", LOG_STACK_SIZE, NULL, LOG_PRI, &logHandle);
if (mlogEnd >= RAM_LOG_LEN) ramLogClear(); // init
LOG_INF("Setup RAM based log, size %u, starting from %u\n\n", RAM_LOG_LEN, mlogEnd);
LOG_INF("=============== %s %s ===============", APP_NAME, APP_VER);
initBrownout();
prepInternalTemp();
LOG_INF("Compiled with arduino-esp32 v%s", ESP_ARDUINO_VERSION_STR);
wakeupResetReason();
if (alertBuffer == NULL) alertBuffer = (byte*)ps_malloc(MAX_ALERT);
if (jsonBuff == NULL) jsonBuff = psramFound() ? (char*)ps_malloc(JSON_BUFF_LEN) : (char*)malloc(JSON_BUFF_LEN);
debugMemory("logSetup");
}
void formatHex(const char* inData, size_t inLen) {
// format data as hex bytes for output
char formatted[(inLen * 3) + 1];
for (int i=0; i<inLen; i++) sprintf(formatted + (i*3), "%02x ", inData[i]);
formatted[(inLen * 3)] = 0; // terminator
LOG_INF("Hex: %s", formatted);
}
const char* espErrMsg(esp_err_t errCode) {
// convert esp error code to text
static char errText[100];
esp_err_to_name_r(errCode, errText, 100);
return errText;
}
void forceCrash() {
// force crash for testing purposes
delay(5000);
#pragma GCC diagnostic ignored "-Wdiv-by-zero"
printf("%u\n", 1/0);
#pragma GCC diagnostic warning "-Wdiv-by-zero"
}
/****************** base 64 ******************/
#define BASE64 "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/"
const uint8_t* encode64chunk(const uint8_t* inp, int rem) {
// receive 3 byte input buffer and return 4 byte base64 buffer
rem = 3 - rem; // last chunk may be less than 3 bytes
uint32_t buff = 0; // hold 3 bytes as shifted 24 bits
static uint8_t b64[4];
// shift input into buffer
for (int i = 0; i < 3 - rem; i++) buff |= inp[i] << (8*(2-i));
// shift 6 bit output from buffer and encode
for (int i = 0; i < 4 - rem; i++) b64[i] = BASE64[buff >> (6*(3-i)) & 0x3F];
// filler for last chunk if less than 3 bytes
for (int i = 0; i < rem; i++) b64[3-i] = '=';
return b64;
}
const char* encode64(const char* inp) {
// helper to base64 encode strings up to 90 chars long
static char encoded[121]; // space for 4/3 expansion + terminator
encoded[0] = 0;
int len = strlen(inp);
if (len > 90) {
LOG_WRN("Input string too long: %u chars", len);
len = 90;
}
for (int i = 0; i < len; i += 3)
strncat(encoded, (char*)encode64chunk((uint8_t*)inp + i, min(len - i, 3)), 4);
return encoded;
}
/************** qualitive core idle time monitoring *************/
// not working properly
#include "esp_freertos_hooks.h"
#define INTERVAL_TIME 100 // reporting interval in ms
#define TICKS_PER_INTERVAL (pdMS_TO_TICKS(INTERVAL_TIME))
static uint32_t idleCalls[portNUM_PROCESSORS] = {0};
static uint32_t idleCnt[portNUM_PROCESSORS];
static bool hookCallback() {
idleCalls[xPortGetCoreID()]++;
return true;
}
uint32_t* reportIdle() {
static uint32_t idlePercent[portNUM_PROCESSORS];
for (int i = 0; i < portNUM_PROCESSORS; i++)
idlePercent[i] = (100 * idleCnt[i]) / TICKS_PER_INTERVAL;
return idlePercent;
}
static void idleMonTask(void* p) {
while (true) {
for (int i = 0; i < portNUM_PROCESSORS; i++) {
idleCnt[i] = idleCalls[i];
idleCalls[i] = 0;
}
vTaskDelay(TICKS_PER_INTERVAL);
}
vTaskDelete(NULL);
}
void startIdleMon() {
// report on each core idle time per interval
// Core 0: wifi, Core 1: Arduino
LOG_INF("Start core idle time monitoring @ interval %ums", INTERVAL_TIME);
for (int i = 0; i < portNUM_PROCESSORS; i++)
esp_register_freertos_idle_hook_for_cpu(hookCallback, i);
xTaskCreatePinnedToCore(idleMonTask, "idlemon", 1024, NULL, IDLEMON_PRI, NULL, 0);