WLED/wled00/fcn_declare.h
Aircoookie dd9da2853a Support settings pin unlock via JSON
Also supports locking by providing any incorrect pin
2023-06-14 11:53:39 +02:00

401 lines
14 KiB
C++

#ifndef WLED_FCN_DECLARE_H
#define WLED_FCN_DECLARE_H
/*
* All globally accessible functions are declared here
*/
//alexa.cpp
#ifndef WLED_DISABLE_ALEXA
void onAlexaChange(EspalexaDevice* dev);
void alexaInit();
void handleAlexa();
void onAlexaChange(EspalexaDevice* dev);
#endif
//button.cpp
void shortPressAction(uint8_t b=0);
void longPressAction(uint8_t b=0);
void doublePressAction(uint8_t b=0);
bool isButtonPressed(uint8_t b=0);
void handleButton();
void handleIO();
//cfg.cpp
bool deserializeConfig(JsonObject doc, bool fromFS = false);
void deserializeConfigFromFS();
bool deserializeConfigSec();
void serializeConfig();
void serializeConfigSec();
template<typename DestType>
bool getJsonValue(const JsonVariant& element, DestType& destination) {
if (element.isNull()) {
return false;
}
destination = element.as<DestType>();
return true;
}
template<typename DestType, typename DefaultType>
bool getJsonValue(const JsonVariant& element, DestType& destination, const DefaultType defaultValue) {
if(!getJsonValue(element, destination)) {
destination = defaultValue;
return false;
}
return true;
}
//colors.cpp
// similar to NeoPixelBus NeoGammaTableMethod but allows dynamic changes (superseded by NPB::NeoGammaDynamicTableMethod)
class NeoGammaWLEDMethod {
public:
static uint8_t Correct(uint8_t value); // apply Gamma to single channel
static uint32_t Correct32(uint32_t color); // apply Gamma to RGBW32 color (WLED specific, not used by NPB)
static void calcGammaTable(float gamma); // re-calculates & fills gamma table
static inline uint8_t rawGamma8(uint8_t val) { return gammaT[val]; } // get value from Gamma table (WLED specific, not used by NPB)
private:
static uint8_t gammaT[];
};
#define gamma32(c) NeoGammaWLEDMethod::Correct32(c)
#define gamma8(c) NeoGammaWLEDMethod::rawGamma8(c)
uint32_t color_blend(uint32_t,uint32_t,uint16_t,bool b16=false);
uint32_t color_add(uint32_t,uint32_t);
inline uint32_t colorFromRgbw(byte* rgbw) { return uint32_t((byte(rgbw[3]) << 24) | (byte(rgbw[0]) << 16) | (byte(rgbw[1]) << 8) | (byte(rgbw[2]))); }
void colorHStoRGB(uint16_t hue, byte sat, byte* rgb); //hue, sat to rgb
void colorKtoRGB(uint16_t kelvin, byte* rgb);
void colorCTtoRGB(uint16_t mired, byte* rgb); //white spectrum to rgb
void colorXYtoRGB(float x, float y, byte* rgb); // only defined if huesync disabled TODO
void colorRGBtoXY(byte* rgb, float* xy); // only defined if huesync disabled TODO
void colorFromDecOrHexString(byte* rgb, char* in);
bool colorFromHexString(byte* rgb, const char* in);
uint32_t colorBalanceFromKelvin(uint16_t kelvin, uint32_t rgb);
uint16_t approximateKelvinFromRGB(uint32_t rgb);
void setRandomColor(byte* rgb);
//dmx.cpp
void initDMX();
void handleDMX();
//e131.cpp
void handleE131Packet(e131_packet_t* p, IPAddress clientIP, byte protocol);
void handleArtnetPollReply(IPAddress ipAddress);
void prepareArtnetPollReply(ArtPollReply* reply);
void sendArtnetPollReply(ArtPollReply* reply, IPAddress ipAddress, uint16_t portAddress);
//file.cpp
bool handleFileRead(AsyncWebServerRequest*, String path);
bool writeObjectToFileUsingId(const char* file, uint16_t id, JsonDocument* content);
bool writeObjectToFile(const char* file, const char* key, JsonDocument* content);
bool readObjectFromFileUsingId(const char* file, uint16_t id, JsonDocument* dest);
bool readObjectFromFile(const char* file, const char* key, JsonDocument* dest);
void updateFSInfo();
void closeFile();
//hue.cpp
void handleHue();
void reconnectHue();
void onHueError(void* arg, AsyncClient* client, int8_t error);
void onHueConnect(void* arg, AsyncClient* client);
void sendHuePoll();
void onHueData(void* arg, AsyncClient* client, void *data, size_t len);
//improv.cpp
void handleImprovPacket();
void sendImprovStateResponse(uint8_t state, bool error = false);
void sendImprovInfoResponse();
void sendImprovRPCResponse(byte commandId);
//ir.cpp
void applyRepeatActions();
byte relativeChange(byte property, int8_t amount, byte lowerBoundary = 0, byte higherBoundary = 0xFF);
void decodeIR(uint32_t code);
void decodeIR24(uint32_t code);
void decodeIR24OLD(uint32_t code);
void decodeIR24CT(uint32_t code);
void decodeIR40(uint32_t code);
void decodeIR44(uint32_t code);
void decodeIR21(uint32_t code);
void decodeIR6(uint32_t code);
void decodeIR9(uint32_t code);
void decodeIRJson(uint32_t code);
void initIR();
void handleIR();
//json.cpp
#include "ESPAsyncWebServer.h"
#include "src/dependencies/json/ArduinoJson-v6.h"
#include "src/dependencies/json/AsyncJson-v6.h"
#include "FX.h"
bool deserializeSegment(JsonObject elem, byte it, byte presetId = 0);
bool deserializeState(JsonObject root, byte callMode = CALL_MODE_DIRECT_CHANGE, byte presetId = 0);
void serializeSegment(JsonObject& root, Segment& seg, byte id, bool forPreset = false, bool segmentBounds = true);
void serializeState(JsonObject root, bool forPreset = false, bool includeBri = true, bool segmentBounds = true, bool selectedSegmentsOnly = false);
void serializeInfo(JsonObject root);
void serializeModeNames(JsonArray root);
void serializeModeData(JsonArray root);
void serveJson(AsyncWebServerRequest* request);
#ifdef WLED_ENABLE_JSONLIVE
bool serveLiveLeds(AsyncWebServerRequest* request, uint32_t wsClient = 0);
#endif
//led.cpp
void setValuesFromSegment(uint8_t s);
void setValuesFromMainSeg();
void setValuesFromFirstSelectedSeg();
void resetTimebase();
void toggleOnOff();
void applyBri();
void applyFinalBri();
void applyValuesToSelectedSegs();
void colorUpdated(byte callMode);
void stateUpdated(byte callMode);
void updateInterfaces(uint8_t callMode);
void handleTransitions();
void handleNightlight();
byte scaledBri(byte in);
#ifdef WLED_ENABLE_LOXONE
//lx_parser.cpp
bool parseLx(int lxValue, byte* rgbw);
void parseLxJson(int lxValue, byte segId, bool secondary);
#endif
//mqtt.cpp
bool initMqtt();
void publishMqtt();
//ntp.cpp
void handleTime();
void handleNetworkTime();
void sendNTPPacket();
bool checkNTPResponse();
void updateLocalTime();
void getTimeString(char* out);
bool checkCountdown();
void setCountdown();
byte weekdayMondayFirst();
void checkTimers();
void calculateSunriseAndSunset();
void setTimeFromAPI(uint32_t timein);
//overlay.cpp
void handleOverlayDraw();
void _overlayAnalogCountdown();
void _overlayAnalogClock();
//playlist.cpp
void shufflePlaylist();
void unloadPlaylist();
int16_t loadPlaylist(JsonObject playlistObject, byte presetId = 0);
void handlePlaylist();
void serializePlaylist(JsonObject obj);
//presets.cpp
void initPresetsFile();
void handlePresets();
bool applyPreset(byte index, byte callMode = CALL_MODE_DIRECT_CHANGE);
inline bool applyTemporaryPreset() {return applyPreset(255);};
void savePreset(byte index, const char* pname = nullptr, JsonObject saveobj = JsonObject());
inline void saveTemporaryPreset() {savePreset(255);};
void deletePreset(byte index);
bool getPresetName(byte index, String& name);
//set.cpp
bool isAsterisksOnly(const char* str, byte maxLen);
void handleSettingsSet(AsyncWebServerRequest *request, byte subPage);
bool handleSet(AsyncWebServerRequest *request, const String& req, bool apply=true);
//udp.cpp
void notify(byte callMode, bool followUp=false);
uint8_t realtimeBroadcast(uint8_t type, IPAddress client, uint16_t length, uint8_t *buffer, uint8_t bri=255, bool isRGBW=false);
void realtimeLock(uint32_t timeoutMs, byte md = REALTIME_MODE_GENERIC);
void exitRealtime();
void handleNotifications();
void setRealtimePixel(uint16_t i, byte r, byte g, byte b, byte w);
void refreshNodeList();
void sendSysInfoUDP();
//network.cpp
int getSignalQuality(int rssi);
void WiFiEvent(WiFiEvent_t event);
//um_manager.cpp
typedef enum UM_Data_Types {
UMT_BYTE = 0,
UMT_UINT16,
UMT_INT16,
UMT_UINT32,
UMT_INT32,
UMT_FLOAT,
UMT_DOUBLE,
UMT_BYTE_ARR,
UMT_UINT16_ARR,
UMT_INT16_ARR,
UMT_UINT32_ARR,
UMT_INT32_ARR,
UMT_FLOAT_ARR,
UMT_DOUBLE_ARR
} um_types_t;
typedef struct UM_Exchange_Data {
// should just use: size_t arr_size, void **arr_ptr, byte *ptr_type
size_t u_size; // size of u_data array
um_types_t *u_type; // array of data types
void **u_data; // array of pointers to data
UM_Exchange_Data() {
u_size = 0;
u_type = nullptr;
u_data = nullptr;
}
~UM_Exchange_Data() {
if (u_type) delete[] u_type;
if (u_data) delete[] u_data;
}
} um_data_t;
const unsigned int um_data_size = sizeof(um_data_t); // 12 bytes
class Usermod {
protected:
um_data_t *um_data; // um_data should be allocated using new in (derived) Usermod's setup() or constructor
public:
Usermod() { um_data = nullptr; }
virtual ~Usermod() { if (um_data) delete um_data; }
virtual void setup() = 0; // pure virtual, has to be overriden
virtual void loop() = 0; // pure virtual, has to be overriden
virtual void handleOverlayDraw() {} // called after all effects have been processed, just before strip.show()
virtual bool handleButton(uint8_t b) { return false; } // button overrides are possible here
virtual bool getUMData(um_data_t **data) { if (data) *data = nullptr; return false; }; // usermod data exchange [see examples for audio effects]
virtual void connected() {} // called when WiFi is (re)connected
virtual void appendConfigData() {} // helper function called from usermod settings page to add metadata for entry fields
virtual void addToJsonState(JsonObject& obj) {} // add JSON objects for WLED state
virtual void addToJsonInfo(JsonObject& obj) {} // add JSON objects for UI Info page
virtual void readFromJsonState(JsonObject& obj) {} // process JSON messages received from web server
virtual void addToConfig(JsonObject& obj) {} // add JSON entries that go to cfg.json
virtual bool readFromConfig(JsonObject& obj) { return true; } // Note as of 2021-06 readFromConfig() now needs to return a bool, see usermod_v2_example.h
virtual void onMqttConnect(bool sessionPresent) {} // fired when MQTT connection is established (so usermod can subscribe)
virtual bool onMqttMessage(char* topic, char* payload) { return false; } // fired upon MQTT message received (wled topic)
virtual void onUpdateBegin(bool) {} // fired prior to and after unsuccessful firmware update
virtual void onStateChange(uint8_t mode) {} // fired upon WLED state change
virtual uint16_t getId() {return USERMOD_ID_UNSPECIFIED;}
};
class UsermodManager {
private:
Usermod* ums[WLED_MAX_USERMODS];
byte numMods = 0;
public:
void loop();
void handleOverlayDraw();
bool handleButton(uint8_t b);
bool getUMData(um_data_t **um_data, uint8_t mod_id = USERMOD_ID_RESERVED); // USERMOD_ID_RESERVED will poll all usermods
void setup();
void connected();
void appendConfigData();
void addToJsonState(JsonObject& obj);
void addToJsonInfo(JsonObject& obj);
void readFromJsonState(JsonObject& obj);
void addToConfig(JsonObject& obj);
bool readFromConfig(JsonObject& obj);
void onMqttConnect(bool sessionPresent);
bool onMqttMessage(char* topic, char* payload);
void onUpdateBegin(bool);
void onStateChange(uint8_t);
bool add(Usermod* um);
Usermod* lookup(uint16_t mod_id);
byte getModCount() {return numMods;};
};
//usermods_list.cpp
void registerUsermods();
//usermod.cpp
void userSetup();
void userConnected();
void userLoop();
//util.cpp
int getNumVal(const String* req, uint16_t pos);
void parseNumber(const char* str, byte* val, byte minv=0, byte maxv=255);
bool getVal(JsonVariant elem, byte* val, byte minv=0, byte maxv=255);
bool updateVal(const char* req, const char* key, byte* val, byte minv=0, byte maxv=255);
bool oappend(const char* txt); // append new c string to temp buffer efficiently
bool oappendi(int i); // append new number to temp buffer efficiently
void sappend(char stype, const char* key, int val);
void sappends(char stype, const char* key, char* val);
void prepareHostname(char* hostname);
bool isAsterisksOnly(const char* str, byte maxLen);
bool requestJSONBufferLock(uint8_t module=255);
void releaseJSONBufferLock();
uint8_t extractModeName(uint8_t mode, const char *src, char *dest, uint8_t maxLen);
uint8_t extractModeSlider(uint8_t mode, uint8_t slider, char *dest, uint8_t maxLen, uint8_t *var = nullptr);
int16_t extractModeDefaults(uint8_t mode, const char *segVar);
void checkSettingsPIN(const char *pin);
uint16_t crc16(const unsigned char* data_p, size_t length);
um_data_t* simulateSound(uint8_t simulationId);
void enumerateLedmaps();
#ifdef WLED_ADD_EEPROM_SUPPORT
//wled_eeprom.cpp
void applyMacro(byte index);
void deEEP();
void deEEPSettings();
void clearEEPROM();
#endif
//wled_math.cpp
#ifndef WLED_USE_REAL_MATH
template <typename T> T atan_t(T x);
float cos_t(float phi);
float sin_t(float x);
float tan_t(float x);
float acos_t(float x);
float asin_t(float x);
float floor_t(float x);
float fmod_t(float num, float denom);
#else
#include <math.h>
#define sin_t sin
#define cos_t cos
#define tan_t tan
#define asin_t asin
#define acos_t acos
#define atan_t atan
#define fmod_t fmod
#define floor_t floor
#endif
//wled_serial.cpp
void handleSerial();
void updateBaudRate(uint32_t rate);
//wled_server.cpp
bool isIp(String str);
void createEditHandler(bool enable);
bool captivePortal(AsyncWebServerRequest *request);
void initServer();
void serveIndexOrWelcome(AsyncWebServerRequest *request);
void serveIndex(AsyncWebServerRequest* request);
String msgProcessor(const String& var);
void serveMessage(AsyncWebServerRequest* request, uint16_t code, const String& headl, const String& subl="", byte optionT=255);
String dmxProcessor(const String& var);
void serveSettings(AsyncWebServerRequest* request, bool post = false);
void serveSettingsJS(AsyncWebServerRequest* request);
//ws.cpp
void handleWs();
void wsEvent(AsyncWebSocket * server, AsyncWebSocketClient * client, AwsEventType type, void * arg, uint8_t *data, size_t len);
void sendDataWs(AsyncWebSocketClient * client = nullptr);
//xml.cpp
void XML_response(AsyncWebServerRequest *request, char* dest = nullptr);
void URL_response(AsyncWebServerRequest *request);
void getSettingsJS(byte subPage, char* dest);
#endif