Fork of the espurna firmware for `mhsw` switches
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/*
DEBUG MODULE
Copyright (C) 2016-2018 by Xose Pérez <xose dot perez at gmail dot com>
Module key prefix: dbg
*/
#if DEBUG_SUPPORT
#include <stdio.h>
#include <stdarg.h>
#include <EEPROM_Rotate.h>
extern "C" {
#include "user_interface.h"
}
#if DEBUG_UDP_SUPPORT
#include <WiFiUdp.h>
WiFiUDP _udp_debug;
#if DEBUG_UDP_PORT == 514
char _udp_syslog_header[40] = {0};
#endif
#endif
#if DEBUG_SERIAL_SUPPORT
HardwareSerial & _dbg_port = DEBUG_PORT;
bool _dbg_serial_enabled = true;
#endif
void _debugSend(char * message) {
bool pause = false;
#if DEBUG_ADD_TIMESTAMP
static bool add_timestamp = true;
char timestamp[10] = {0};
if (add_timestamp) snprintf_P(timestamp, sizeof(timestamp), PSTR("[%06lu] "), millis() % 1000000);
add_timestamp = (message[strlen(message)-1] == 10) || (message[strlen(message)-1] == 13);
#endif
#if DEBUG_SERIAL_SUPPORT
if (_dbg_serial_enabled) {
#if DEBUG_ADD_TIMESTAMP
_dbg_port.printf(timestamp);
#endif
_dbg_port.printf(message);
}
#endif
#if DEBUG_UDP_SUPPORT
#if SYSTEM_CHECK_ENABLED
if (systemCheck()) {
#endif
_udp_debug.beginPacket(DEBUG_UDP_IP, DEBUG_UDP_PORT);
#if DEBUG_UDP_PORT == 514
_udp_debug.write(_udp_syslog_header);
#endif
_udp_debug.write(message);
_udp_debug.endPacket();
pause = true;
#if SYSTEM_CHECK_ENABLED
}
#endif
#endif
#if DEBUG_TELNET_SUPPORT
#if DEBUG_ADD_TIMESTAMP
_telnetWrite(timestamp, strlen(timestamp));
#endif
_telnetWrite(message, strlen(message));
pause = true;
#endif
#if DEBUG_WEB_SUPPORT
if (wsConnected() && (getFreeHeap() > 10000)) {
DynamicJsonBuffer jsonBuffer(JSON_OBJECT_SIZE(1) + strlen(message) + 17);
JsonObject &root = jsonBuffer.createObject();
#if DEBUG_ADD_TIMESTAMP
char buffer[strlen(timestamp) + strlen(message) + 1];
snprintf_P(buffer, sizeof(buffer), "%s%s", timestamp, message);
root.set("weblog", buffer);
#else
root.set("weblog", message);
#endif
String out;
root.printTo(out);
jsonBuffer.clear();
wsSend(out.c_str());
pause = true;
}
#endif
if (pause) optimistic_yield(100);
}
// -----------------------------------------------------------------------------
void debugSend(const char * format, ...) {
va_list args;
va_start(args, format);
char test[1];
int len = ets_vsnprintf(test, 1, format, args) + 1;
char * buffer = new char[len];
ets_vsnprintf(buffer, len, format, args);
va_end(args);
_debugSend(buffer);
delete[] buffer;
}
void debugSend_P(PGM_P format_P, ...) {
char format[strlen_P(format_P)+1];
memcpy_P(format, format_P, sizeof(format));
va_list args;
va_start(args, format_P);
char test[1];
int len = ets_vsnprintf(test, 1, format, args) + 1;
char * buffer = new char[len];
ets_vsnprintf(buffer, len, format, args);
va_end(args);
_debugSend(buffer);
delete[] buffer;
}
#if DEBUG_WEB_SUPPORT
void debugWebSetup() {
wsOnSendRegister([](JsonObject& root) {
root["dbgVisible"] = 1;
});
wsOnActionRegister([](uint32_t client_id, const char * action, JsonObject& data) {
if (strcmp(action, "dbgcmd") == 0) {
const char* command = data.get<const char*>("command");
char buffer[strlen(command) + 2];
snprintf(buffer, sizeof(buffer), "%s\n", command);
settingsInject((void*) buffer, strlen(buffer));
}
});
#if DEBUG_UDP_SUPPORT
#if DEBUG_UDP_PORT == 514
snprintf_P(_udp_syslog_header, sizeof(_udp_syslog_header), PSTR("<%u>%s ESPurna[0]: "), DEBUG_UDP_FAC_PRI, getHostname().c_str());
#endif
#endif
}
#endif // DEBUG_WEB_SUPPORT
bool _debugKeyCheck(const char * key) {
return (strncmp(key, "dbg", 3) == 0);
}
int debugSerialAvailable() {
#if DEBUG_SERIAL_SUPPORT
if (_dbg_serial_enabled) {
return _dbg_port.available();
}
#endif
return 0;
}
int debugSerialRead() {
#if DEBUG_SERIAL_SUPPORT
if (_dbg_serial_enabled) {
return _dbg_port.read();
}
#endif
return 0;
}
void debugSerialWrite(uint8_t ch) {
#if DEBUG_SERIAL_SUPPORT
if (_dbg_serial_enabled) {
_dbg_port.write(ch);
}
#endif
}
void debugSetup() {
#if DEBUG_SERIAL_SUPPORT
_dbg_serial_enabled = getSetting("dbgSerial", 1).toInt() == 1;
if (_dbg_serial_enabled) {
unsigned char port = getSetting("dbgPort", 0).toInt();
if (0 == port) {
_dbg_port = Serial;
} else {
_dbg_port = Serial1;
}
unsigned long speed = getSetting("dbgSpeed", DEBUG_SERIAL_SPEED).toInt();
_dbg_port.begin(speed);
#if DEBUG_ESP_WIFI
_dbg_port.setDebugOutput(true);
#endif
}
#endif
settingsRegisterKeyCheck(_debugKeyCheck);
}
// -----------------------------------------------------------------------------
// Save crash info
// Taken from krzychb EspSaveCrash
// https://github.com/krzychb/EspSaveCrash
// -----------------------------------------------------------------------------
#define SAVE_CRASH_EEPROM_OFFSET 0x0100 // initial address for crash data
/**
* Structure of the single crash data set
*
* 1. Crash time
* 2. Restart reason
* 3. Exception cause
* 4. epc1
* 5. epc2
* 6. epc3
* 7. excvaddr
* 8. depc
* 9. adress of stack start
* 10. adress of stack end
* 11. stack trace bytes
* ...
*/
#define SAVE_CRASH_CRASH_TIME 0x00 // 4 bytes
#define SAVE_CRASH_RESTART_REASON 0x04 // 1 byte
#define SAVE_CRASH_EXCEPTION_CAUSE 0x05 // 1 byte
#define SAVE_CRASH_EPC1 0x06 // 4 bytes
#define SAVE_CRASH_EPC2 0x0A // 4 bytes
#define SAVE_CRASH_EPC3 0x0E // 4 bytes
#define SAVE_CRASH_EXCVADDR 0x12 // 4 bytes
#define SAVE_CRASH_DEPC 0x16 // 4 bytes
#define SAVE_CRASH_STACK_START 0x1A // 4 bytes
#define SAVE_CRASH_STACK_END 0x1E // 4 bytes
#define SAVE_CRASH_STACK_TRACE 0x22 // variable
/**
* Save crash information in EEPROM
* This function is called automatically if ESP8266 suffers an exception
* It should be kept quick / consise to be able to execute before hardware wdt may kick in
*/
extern "C" void custom_crash_callback(struct rst_info * rst_info, uint32_t stack_start, uint32_t stack_end ) {
// This method assumes EEPROM has already been initialized
// which is the first thing ESPurna does
// write crash time to EEPROM
uint32_t crash_time = millis();
EEPROMr.put(SAVE_CRASH_EEPROM_OFFSET + SAVE_CRASH_CRASH_TIME, crash_time);
// write reset info to EEPROM
EEPROMr.write(SAVE_CRASH_EEPROM_OFFSET + SAVE_CRASH_RESTART_REASON, rst_info->reason);
EEPROMr.write(SAVE_CRASH_EEPROM_OFFSET + SAVE_CRASH_EXCEPTION_CAUSE, rst_info->exccause);
// write epc1, epc2, epc3, excvaddr and depc to EEPROM
EEPROMr.put(SAVE_CRASH_EEPROM_OFFSET + SAVE_CRASH_EPC1, rst_info->epc1);
EEPROMr.put(SAVE_CRASH_EEPROM_OFFSET + SAVE_CRASH_EPC2, rst_info->epc2);
EEPROMr.put(SAVE_CRASH_EEPROM_OFFSET + SAVE_CRASH_EPC3, rst_info->epc3);
EEPROMr.put(SAVE_CRASH_EEPROM_OFFSET + SAVE_CRASH_EXCVADDR, rst_info->excvaddr);
EEPROMr.put(SAVE_CRASH_EEPROM_OFFSET + SAVE_CRASH_DEPC, rst_info->depc);
// write stack start and end address to EEPROM
EEPROMr.put(SAVE_CRASH_EEPROM_OFFSET + SAVE_CRASH_STACK_START, stack_start);
EEPROMr.put(SAVE_CRASH_EEPROM_OFFSET + SAVE_CRASH_STACK_END, stack_end);
// write stack trace to EEPROM
int16_t current_address = SAVE_CRASH_EEPROM_OFFSET + SAVE_CRASH_STACK_TRACE;
for (uint32_t i = stack_start; i < stack_end; i++) {
byte* byteValue = (byte*) i;
EEPROMr.write(current_address++, *byteValue);
}
EEPROMr.commit();
}
/**
* Clears crash info
*/
void debugClearCrashInfo() {
uint32_t crash_time = 0xFFFFFFFF;
EEPROMr.put(SAVE_CRASH_EEPROM_OFFSET + SAVE_CRASH_CRASH_TIME, crash_time);
EEPROMr.commit();
}
/**
* Print out crash information that has been previusly saved in EEPROM
*/
void debugDumpCrashInfo() {
uint32_t crash_time;
EEPROMr.get(SAVE_CRASH_EEPROM_OFFSET + SAVE_CRASH_CRASH_TIME, crash_time);
if ((crash_time == 0) || (crash_time == 0xFFFFFFFF)) {
DEBUG_MSG_P(PSTR("[DEBUG] No crash info\n"));
return;
}
DEBUG_MSG_P(PSTR("[DEBUG] Latest crash was at %lu ms after boot\n"), crash_time);
DEBUG_MSG_P(PSTR("[DEBUG] Reason of restart: %u\n"), EEPROMr.read(SAVE_CRASH_EEPROM_OFFSET + SAVE_CRASH_RESTART_REASON));
DEBUG_MSG_P(PSTR("[DEBUG] Exception cause: %u\n"), EEPROMr.read(SAVE_CRASH_EEPROM_OFFSET + SAVE_CRASH_EXCEPTION_CAUSE));
uint32_t epc1, epc2, epc3, excvaddr, depc;
EEPROMr.get(SAVE_CRASH_EEPROM_OFFSET + SAVE_CRASH_EPC1, epc1);
EEPROMr.get(SAVE_CRASH_EEPROM_OFFSET + SAVE_CRASH_EPC2, epc2);
EEPROMr.get(SAVE_CRASH_EEPROM_OFFSET + SAVE_CRASH_EPC3, epc3);
EEPROMr.get(SAVE_CRASH_EEPROM_OFFSET + SAVE_CRASH_EXCVADDR, excvaddr);
EEPROMr.get(SAVE_CRASH_EEPROM_OFFSET + SAVE_CRASH_DEPC, depc);
DEBUG_MSG_P(PSTR("[DEBUG] epc1=0x%08x epc2=0x%08x epc3=0x%08x\n"), epc1, epc2, epc3);
DEBUG_MSG_P(PSTR("[DEBUG] excvaddr=0x%08x depc=0x%08x\n"), excvaddr, depc);
uint32_t stack_start, stack_end;
EEPROMr.get(SAVE_CRASH_EEPROM_OFFSET + SAVE_CRASH_STACK_START, stack_start);
EEPROMr.get(SAVE_CRASH_EEPROM_OFFSET + SAVE_CRASH_STACK_END, stack_end);
DEBUG_MSG_P(PSTR("[DEBUG] >>>stack>>>\n[DEBUG] "));
int16_t current_address = SAVE_CRASH_EEPROM_OFFSET + SAVE_CRASH_STACK_TRACE;
int16_t stack_len = stack_end - stack_start;
uint32_t stack_trace;
for (int16_t i = 0; i < stack_len; i += 0x10) {
DEBUG_MSG_P(PSTR("%08x: "), stack_start + i);
for (byte j = 0; j < 4; j++) {
EEPROMr.get(current_address, stack_trace);
DEBUG_MSG_P(PSTR("%08x "), stack_trace);
current_address += 4;
}
DEBUG_MSG_P(PSTR("\n[DEBUG] "));
}
DEBUG_MSG_P(PSTR("<<<stack<<<\n"));
}
#endif // DEBUG_SUPPORT