Tasmota/tasmota/xdrv_23_zigbee_2_devices.ino

745 lines
29 KiB
C++

/*
xdrv_23_zigbee.ino - zigbee support for Tasmota
Copyright (C) 2020 Theo Arends and Stephan Hadinger
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/>.
*/
#ifdef USE_ZIGBEE
#ifndef ZIGBEE_SAVE_DELAY_SECONDS
#define ZIGBEE_SAVE_DELAY_SECONDS 2 // wait for 2s before saving Zigbee info
#endif
const uint16_t kZigbeeSaveDelaySeconds = ZIGBEE_SAVE_DELAY_SECONDS; // wait for x seconds
enum class Z_Data_Type : uint8_t {
Z_Unknown = 0x00,
Z_Light = 1, // Lights 1-5 channels
Z_Plug = 2, // Plug power consumption
Z_PIR = 3,
Z_Alarm = 4,
Z_Thermo = 5, // Thermostat and sensor for home environment (temp, himudity, pressure)
Z_OnOff = 6, // OnOff, Buttons and Relays (always complements Lights and Plugs)
Z_Ext = 0xF, // extended for other values
Z_Device = 0xFF // special value when parsing Device level attributes
};
const uint8_t Z_Data_Type_char[] PROGMEM = {
'?', // 0x00 Z_Data_Type::Z_Unknown
'L', // 0x01 Z_Data_Type::Z_Light
'P', // 0x02 Z_Data_Type::Z_Plug
'I', // 0x03 Z_Data_Type::Z_PIR
'A', // 0x04 Z_Data_Type::Z_Alarm
'T', // 0x05 Z_Data_Type::Z_Thermo
'O', // 0x05 Z_Data_Type::Z_OnOff
'\0', // 0x06
'\0', // 0x07
'\0', // 0x08
'\0', // 0x09
'\0', // 0x0A
'\0', // 0x0B
'\0', // 0x0C
'\0', // 0x0D
'\0', // 0x0E
'E', // 0x05 Z_Data_Type::Z_Ext
// '_' maps to 0xFF Z_Data_Type::Z_Device
};
class Z_Data_Set;
/*********************************************************************************************\
* Device specific data, sensors...
\*********************************************************************************************/
class Z_Data {
public:
Z_Data(Z_Data_Type type = Z_Data_Type::Z_Unknown, uint8_t endpoint = 0) : _type(type), _endpoint(endpoint), _config(0xF), _power(0) {}
inline Z_Data_Type getType(void) const { return _type; }
inline int8_t getConfig(void) const { return _config; }
inline bool validConfig(void) const { return _config != 0xF; }
inline void setConfig(int8_t config) { _config = config; }
uint8_t getConfigByte(void) const { return ( ((uint8_t)_type) << 4) | ((_config & 0xF) & 0x0F); }
inline uint8_t getEndpoint(void) const { return _endpoint; }
void toAttributes(Z_attribute_list & attr_list, Z_Data_Type type) const;
static const Z_Data_Type type = Z_Data_Type::Z_Unknown;
static bool ConfigToZData(const char * config_str, Z_Data_Type * type, uint8_t * ep, uint8_t * config);
static Z_Data_Type CharToDataType(char c);
static char DataTypeToChar(Z_Data_Type t);
friend class Z_Data_Set;
protected:
Z_Data_Type _type; // encoded on 4 bits, type of the device
uint8_t _endpoint; // source endpoint, or 0x00 if any endpoint
uint8_t _config : 4; // encoded on 4 bits, customize behavior
uint8_t _power; // power state if the type supports it
};
Z_Data_Type Z_Data::CharToDataType(char c) {
if (c) {
if (c == '_') {
return Z_Data_Type::Z_Device;
} else {
for (uint32_t i=0; i<ARRAY_SIZE(Z_Data_Type_char); i++) {
if (pgm_read_byte(&Z_Data_Type_char[i]) == c) {
return (Z_Data_Type) i;
}
}
}
}
return Z_Data_Type::Z_Unknown;
}
char Z_Data::DataTypeToChar(Z_Data_Type t) {
if (t == Z_Data_Type::Z_Device) {
return '_';
} else {
uint8_t tt = (uint8_t) t;
if (tt < ARRAY_SIZE(Z_Data_Type_char)) {
return pgm_read_byte(&Z_Data_Type_char[tt]);
}
}
return '\0';
}
// Parse configuration
// Either '_'
// or 'T01' or 'L01.2'
// result: true if parsing ok
bool Z_Data::ConfigToZData(const char * config_str, Z_Data_Type * type, uint8_t * ep, uint8_t * config) {
if (config_str == nullptr) { return false; }
Z_Data_Type data_type = Z_Data::CharToDataType(config_str[0]);
if (data_type == Z_Data_Type::Z_Unknown) {
return false;
}
if (type != nullptr) {
*type = data_type;
}
if (ep != nullptr) {
*ep = strtoul(&config_str[1], nullptr, 16); // hex base 16
}
if ((config != nullptr) && (config_str[3] == '.')) {
// we have a config attribute
*config = strtoul(&config_str[4], nullptr, 16) & 0x0F; // hex base 16
}
return true;
}
/*********************************************************************************************\
* Device specific: On/Off, power up to 8 relays
\*********************************************************************************************/
// _config contains the number of valid OnOff relays: 0..7
// _power contains a bitfield of relays values
class Z_Data_OnOff : public Z_Data {
public:
Z_Data_OnOff(uint8_t endpoint = 0) :
Z_Data(Z_Data_Type::Z_OnOff, endpoint)
{
_config = 1; // at least 1 OnOff
}
inline bool validPower(uint32_t relay = 0) const { return (_config > relay); } // power is declared
inline bool getPower(uint32_t relay = 0) const { return bitRead(_power, relay); }
void setPower(bool val, uint32_t relay = 0);
void toAttributes(Z_attribute_list & attr_list, Z_Data_Type type) const;
static const Z_Data_Type type = Z_Data_Type::Z_OnOff;
};
void Z_Data_OnOff::setPower(bool val, uint32_t relay) {
if (relay < 8) {
if (_config < relay) { _config = relay; } // we update the number of valid relays
bitWrite(_power, relay, val);
}
}
/*********************************************************************************************\
* Device specific: Light device
\*********************************************************************************************/
class Z_Data_Plug : public Z_Data {
public:
Z_Data_Plug(uint8_t endpoint = 0) :
Z_Data(Z_Data_Type::Z_Plug, endpoint),
mains_voltage(0xFFFF),
mains_power(-0x8000)
{}
inline bool validMainsVoltage(void) const { return 0xFFFF != mains_voltage; }
inline bool validMainsPower(void) const { return -0x8000 != mains_power; }
inline uint16_t getMainsVoltage(void) const { return mains_voltage; }
inline int16_t getMainsPower(void) const { return mains_power; }
inline void setMainsVoltage(uint16_t _mains_voltage) { mains_voltage = _mains_voltage; }
inline void setMainsPower(int16_t _mains_power) { mains_power = _mains_power; }
static const Z_Data_Type type = Z_Data_Type::Z_Plug;
// 4 bytes
uint16_t mains_voltage; // AC voltage
int16_t mains_power; // Active power
};
/*********************************************************************************************\
* Device specific: Light device
\*********************************************************************************************/
class Z_Data_Light : public Z_Data {
public:
Z_Data_Light(uint8_t endpoint = 0) :
Z_Data(Z_Data_Type::Z_Light, endpoint),
colormode(0xFF),
dimmer(0xFF),
sat(0xFF),
hue(0xFF),
ct(0xFFFF),
x(0xFFFF),
y(0xFFFF)
{}
inline bool validColormode(void) const { return 0xFF != colormode; }
inline bool validDimmer(void) const { return 0xFF != dimmer; }
inline bool validSat(void) const { return 0xFF != sat; }
inline bool validHue(void) const { return 0xFFFF != hue; }
inline bool validCT(void) const { return 0xFFFF != ct; }
inline bool validX(void) const { return 0xFFFF != x; }
inline bool validY(void) const { return 0xFFFF != y; }
inline uint8_t getColorMode(void) const { return colormode; }
inline uint8_t getDimmer(void) const { return dimmer; }
inline uint8_t getSat(void) const { return sat; }
inline uint16_t getHue(void) const { return changeUIntScale(hue, 0, 254, 0, 360); }
inline uint16_t getCT(void) const { return ct; }
inline uint16_t getX(void) const { return x; }
inline uint16_t getY(void) const { return y; }
inline void setColorMode(uint8_t _colormode) { colormode = _colormode; }
inline void setDimmer(uint8_t _dimmer) { dimmer = _dimmer; }
inline void setSat(uint8_t _sat) { sat = _sat; }
inline void setHue(uint16_t _hue) { hue = changeUIntScale(_hue, 0, 360, 0, 254);; }
inline void setCT(uint16_t _ct) { ct = _ct; }
inline void setX(uint16_t _x) { x = _x; }
inline void setY(uint16_t _y) { y = _y; }
static const Z_Data_Type type = Z_Data_Type::Z_Light;
// 12 bytes
uint8_t colormode; // 0x00: Hue/Sat, 0x01: XY, 0x02: CT | 0xFF not set, default 0x01
uint8_t dimmer; // last Dimmer value: 0-254 | 0xFF not set, default 0x00
uint8_t sat; // last Sat: 0..254 | 0xFF not set, default 0x00
uint8_t hue; // last Hue: 0..359 | 0xFFFF not set, default 0
uint16_t ct; // last CT: 153-500 | 0xFFFF not set, default 200
uint16_t x, y; // last color [x,y] | 0xFFFF not set, default 0
};
/*********************************************************************************************\
* Device specific: PIR
\*********************************************************************************************/
class Z_Data_PIR : public Z_Data {
public:
Z_Data_PIR(uint8_t endpoint = 0) :
Z_Data(Z_Data_Type::Z_PIR, endpoint),
occupancy(0xFF),
illuminance(0xFFFF)
{}
inline bool validOccupancy(void) const { return 0xFF != occupancy; }
inline bool validIlluminance(void) const { return 0xFFFF != illuminance; }
inline uint8_t getOccupancy(void) const { return occupancy; }
inline uint16_t getIlluminance(void) const { return illuminance; }
inline void setOccupancy(uint8_t _occupancy) { occupancy = _occupancy; }
inline void setilluminance(uint16_t _illuminance) { illuminance = _illuminance; }
static const Z_Data_Type type = Z_Data_Type::Z_PIR;
// PIR
uint8_t occupancy; // map8
uint16_t illuminance; // illuminance
};
/*********************************************************************************************\
* Device specific: Sensors: temp, humidity, pressure...
\*********************************************************************************************/
class Z_Data_Thermo : public Z_Data {
public:
Z_Data_Thermo(uint8_t endpoint = 0) :
Z_Data(Z_Data_Type::Z_Thermo, endpoint),
temperature(-0x8000),
pressure(-0x8000),
humidity(0xFFFF),
th_setpoint(0xFF),
temperature_target(-0x8000)
{}
inline bool validTemperature(void) const { return -0x8000 != temperature; }
inline bool validPressure(void) const { return -0x8000 != pressure; }
inline bool validHumidity(void) const { return 0xFFFF != humidity; }
inline bool validThSetpoint(void) const { return 0xFF != th_setpoint; }
inline bool validTempTarget(void) const { return -0x8000 != temperature_target; }
inline int16_t getTemperature(void) const { return temperature; }
inline int16_t getPressure(void) const { return pressure; }
inline uint16_t getHumidity(void) const { return humidity; }
inline uint8_t getThSetpoint(void) const { return th_setpoint; }
inline int16_t getTempTarget(void) const { return temperature_target; }
inline void setTemperature(int16_t _temperature) { temperature = _temperature; }
inline void setPressure(int16_t _pressure) { pressure = _pressure; }
inline void setHumidity(uint16_t _humidity) { humidity = _humidity; }
inline void setThSetpoint(uint8_t _th_setpoint) { th_setpoint = _th_setpoint; }
inline void setTempTarget(int16_t _temperature_target){ temperature_target = _temperature_target; }
static const Z_Data_Type type = Z_Data_Type::Z_Thermo;
// 8 bytes
// sensor data
int16_t temperature; // temperature in 1/10th of Celsius, 0x8000 if unknown
int16_t pressure; // air pressure in hPa, 0xFFFF if unknown
uint16_t humidity; // humidity in percent, 0..100, 0xFF if unknown
// thermostat
uint8_t th_setpoint; // percentage of heat/cool in percent
int16_t temperature_target; // settings for the temparature
};
/*********************************************************************************************\
* Device specific: Alarm
\*********************************************************************************************/
class Z_Data_Alarm : public Z_Data {
public:
Z_Data_Alarm(uint8_t endpoint = 0) :
Z_Data(Z_Data_Type::Z_Alarm, endpoint),
zone_type(0xFFFF)
{}
static const Z_Data_Type type = Z_Data_Type::Z_Alarm;
inline bool validZoneType(void) const { return 0xFFFF != zone_type; }
inline uint16_t getZoneType(void) const { return zone_type; }
inline void setZoneType(uint16_t _zone_type) { zone_type = _zone_type; }
// 4 bytes
uint16_t zone_type; // mapped to the Zigbee standard
// 0x0000 Standard CIE
// 0x000d Motion sensor
// 0x0015 Contact switch
// 0x0028 Fire sensor
// 0x002a Water sensor
// 0x002b Carbon Monoxide (CO) sensor
// 0x002c Personal emergency device
// 0x002d Vibration/Movement sensor
// 0x010f Remote Control
// 0x0115 Key fob
// 0x021d Keypad
// 0x0225 Standard Warning Device (see [N1] part 4)
// 0x0226 Glass break sensor
// 0x0229 Security repeater*
};
/*********************************************************************************************\
*
* Device specific Linked List
*
\*********************************************************************************************/
class Z_Data_Set : public LList<Z_Data> {
public:
// List<Z_Data>() : List<Z_Data>() {}
Z_Data & getByType(Z_Data_Type type, uint8_t ep = 0); // creates if non-existent
const Z_Data & find(Z_Data_Type type, uint8_t ep = 0) const;
// getX() always returns a valid object, and creates the object if there is none
// find() does not create an object if it does not exist, and returns *(X*)nullptr
template <class M>
M & get(uint8_t ep = 0);
template <class M>
const M & find(uint8_t ep = 0) const;
// check if the point is null, if so create a new object with the right sub-class
template <class M>
M & addIfNull(M & cur, uint8_t ep = 0);
};
Z_Data & Z_Data_Set::getByType(Z_Data_Type type, uint8_t ep) {
switch (type) {
case Z_Data_Type::Z_Light:
return get<Z_Data_Light>(ep);
case Z_Data_Type::Z_Plug:
return get<Z_Data_Plug>(ep);
case Z_Data_Type::Z_Alarm:
return get<Z_Data_Alarm>(ep);
case Z_Data_Type::Z_Thermo:
return get<Z_Data_Thermo>(ep);
case Z_Data_Type::Z_OnOff:
return get<Z_Data_OnOff>(ep);
case Z_Data_Type::Z_PIR:
return get<Z_Data_PIR>(ep);
default:
return *(Z_Data*)nullptr;
}
}
template <class M>
M & Z_Data_Set::get(uint8_t ep) {
M & m = (M&) find(M::type, ep);
return addIfNull<M>(m, ep);
}
template <class M>
const M & Z_Data_Set::find(uint8_t ep) const {
return (M&) find(M::type, ep);
}
// Input: reference to object
// Output: if reference is null, instantiate object and add it at the end of the list
template <class M>
M & Z_Data_Set::addIfNull(M & cur, uint8_t ep) {
if (nullptr == &cur) {
LList_elt<M> * elt = new LList_elt<M>();
elt->val()._endpoint = ep;
this->addToLast((LList_elt<Z_Data>*)elt);
return elt->val();
} else {
if (cur._endpoint == 0) { cur._endpoint = ep; } // be more specific on endpoint
return cur;
}
}
const Z_Data & Z_Data_Set::find(Z_Data_Type type, uint8_t ep) const {
for (auto & elt : *this) {
if (elt._type == type) {
// type matches, check if ep matches.
// 0 matches all endpoints
if ((ep == 0) || (elt._endpoint == 0) || (ep == elt._endpoint)) {
return elt;
}
}
}
return *(Z_Data*)nullptr;
}
void Z_Data_OnOff::toAttributes(Z_attribute_list & attr_list, Z_Data_Type type) const {
if (validPower()) { attr_list.addAttribute(PSTR("Power")).setUInt(getPower() ? 1 : 0); }
}
/*********************************************************************************************\
* Structures for Rules variables related to the last received message
\*********************************************************************************************/
const size_t endpoints_max = 8; // we limit to 8 endpoints
class Z_Device {
public:
uint64_t longaddr; // 0x00 means unspecified
char * manufacturerId;
char * modelId;
char * friendlyName;
// _defer_last_time : what was the last time an outgoing message is scheduled
// this is designed for flow control and avoid messages to be lost or unanswered
uint32_t defer_last_message_sent;
uint8_t endpoints[endpoints_max]; // static array to limit memory consumption, list of endpoints until 0x00 or end of array
// Used for attribute reporting
Z_attribute_list attr_list;
// sequence number for Zigbee frames
uint16_t shortaddr; // unique key if not null, or unspecified if null
uint8_t seqNumber;
bool hidden;
bool reachable;
// Light information for Hue integration integration, last known values
// New version of device data handling
Z_Data_Set data; // Linkedlist of device data per endpoint
// other status
uint8_t lqi; // lqi from last message, 0xFF means unknown
uint8_t batterypercent; // battery percentage (0..100), 0xFF means unknwon
// power plug data-
uint32_t last_seen; // Last seen time (epoch)
// Constructor with all defaults
Z_Device(uint16_t _shortaddr = BAD_SHORTADDR, uint64_t _longaddr = 0x00):
longaddr(_longaddr),
manufacturerId(nullptr),
modelId(nullptr),
friendlyName(nullptr),
defer_last_message_sent(0),
endpoints{ 0, 0, 0, 0, 0, 0, 0, 0 },
attr_list(),
shortaddr(_shortaddr),
seqNumber(0),
hidden(false),
reachable(false),
data(),
lqi(0xFF),
batterypercent(0xFF),
last_seen(0)
{ };
inline bool valid(void) const { return BAD_SHORTADDR != shortaddr; } // is the device known, valid and found?
inline bool validLongaddr(void) const { return 0x0000 != longaddr; }
inline bool validManufacturerId(void) const { return nullptr != manufacturerId; }
inline bool validModelId(void) const { return nullptr != modelId; }
inline bool validFriendlyName(void) const { return nullptr != friendlyName; }
inline bool validPower(uint8_t ep =0) const;
inline bool validLqi(void) const { return 0xFF != lqi; }
inline bool validBatteryPercent(void) const { return 0xFF != batterypercent; }
inline bool validLastSeen(void) const { return 0x0 != last_seen; }
inline void setReachable(bool _reachable) { reachable = _reachable; }
inline bool getReachable(void) const { return reachable; }
inline bool getPower(uint8_t ep =0) const;
// dump device attributes to ZbData
void toAttributes(Z_attribute_list & attr_list) const;
// Device data specific
void setPower(bool power_on, uint8_t ep = 0);
// If light, returns the number of channels, or 0xFF if unknown
int8_t getLightChannels(void) const {
const Z_Data_Light & light = data.find<Z_Data_Light>(0);
if (&light != nullptr) {
return light.getConfig();
} else {
return -1;
}
}
// returns: dirty flag, did we change the value of the object
bool setLightChannels(int8_t channels) {
bool dirty = false;
if (channels >= 0) {
// retrieve of create light object
Z_Data_Light & light = data.get<Z_Data_Light>(0);
if (channels != light.getConfig()) {
light.setConfig(channels);
dirty = true;
}
Z_Data_OnOff & onoff = data.get<Z_Data_OnOff>(0);
} else {
// remove light / onoff object if any
for (auto & data_elt : data) {
if ((data_elt.getType() == Z_Data_Type::Z_Light) ||
(data_elt.getType() == Z_Data_Type::Z_OnOff)) {
// remove light object
data.remove(&data_elt);
dirty = true;
}
}
}
return dirty;
}
};
/*********************************************************************************************\
* Structures for deferred callbacks
\*********************************************************************************************/
typedef void (*Z_DeviceTimer)(uint16_t shortaddr, uint16_t groupaddr, uint16_t cluster, uint8_t endpoint, uint32_t value);
// Category for Deferred actions, this allows to selectively remove active deferred or update them
typedef enum Z_Def_Category {
Z_CAT_ALWAYS = 0, // no category, it will happen whatever new timers
// Below will clear any event in the same category for the same address (shortaddr / groupaddr)
Z_CLEAR_DEVICE = 0x01,
Z_CAT_READ_ATTR, // Attribute reporting, either READ_ATTRIBUTE or REPORT_ATTRIBUTE, we coalesce all attributes reported if we can
Z_CAT_VIRTUAL_OCCUPANCY, // Creation of a virtual attribute, typically after a time-out. Ex: Aqara presence sensor
Z_CAT_REACHABILITY, // timer set to measure reachability of device, i.e. if we don't get an answer after 1s, it is marked as unreachable (for Alexa)
Z_CAT_PERMIT_JOIN, // timer to signal the end of the PermitJoin period
// Below will clear based on device + cluster pair.
Z_CLEAR_DEVICE_CLUSTER,
Z_CAT_READ_CLUSTER,
// Below will clear based on device + cluster + endpoint
Z_CLEAR_DEVICE_CLUSTER_ENDPOINT,
Z_CAT_EP_DESC, // read endpoint descriptor to gather clusters
Z_CAT_BIND, // send auto-binding to coordinator
Z_CAT_CONFIG_ATTR, // send a config attribute reporting request
Z_CAT_READ_ATTRIBUTE, // read a single attribute
} Z_Def_Category;
const uint32_t Z_CAT_REACHABILITY_TIMEOUT = 2000; // 1000 ms or 1s
typedef struct Z_Deferred {
// below are per device timers, used for example to query the new state of the device
uint32_t timer; // millis() when to fire the timer, 0 if no timer
uint16_t shortaddr; // identifier of the device
uint16_t groupaddr; // group address (if needed)
uint16_t cluster; // cluster to use for the timer
uint8_t endpoint; // endpoint to use for timer
uint8_t category; // which category of deferred is it
uint32_t value; // any raw value to use for the timer
Z_DeviceTimer func; // function to call when timer occurs
} Z_Deferred;
/*********************************************************************************************\
* Singleton for device configuration
\*********************************************************************************************/
// All devices are stored in a Vector
// Invariants:
// - shortaddr is unique if not null
// - longaddr is unique if not null
// - shortaddr and longaddr cannot be both null
class Z_Devices {
public:
Z_Devices() : _deferred() {};
// Probe the existence of device keys
// Results:
// - 0x0000 = not found
// - BAD_SHORTADDR = bad parameter
// - 0x<shortaddr> = the device's short address
uint16_t isKnownLongAddr(uint64_t longaddr) const;
uint16_t isKnownIndex(uint32_t index) const;
uint16_t isKnownFriendlyName(const char * name) const;
Z_Device & findShortAddr(uint16_t shortaddr);
const Z_Device & findShortAddr(uint16_t shortaddr) const;
Z_Device & findLongAddr(uint64_t longaddr);
const Z_Device & findLongAddr(uint64_t longaddr) const;
Z_Device & getShortAddr(uint16_t shortaddr); // find Device from shortAddr, creates it if does not exist
Z_Device & getLongAddr(uint64_t longaddr); // find Device from shortAddr, creates it if does not exist
// check if a device was found or if it's the fallback device
inline bool foundDevice(const Z_Device & device) const {
return (&device != &device_unk);
}
int32_t findFriendlyName(const char * name) const;
uint64_t getDeviceLongAddr(uint16_t shortaddr) const;
uint8_t findFirstEndpoint(uint16_t shortaddr) const;
// Add new device, provide ShortAddr and optional longAddr
// If it is already registered, update information, otherwise create the entry
Z_Device & updateDevice(uint16_t shortaddr, uint64_t longaddr = 0);
// Add an endpoint to a device
void addEndpoint(uint16_t shortaddr, uint8_t endpoint);
void clearEndpoints(uint16_t shortaddr);
uint32_t countEndpoints(uint16_t shortaddr) const; // return the number of known endpoints (0 if unknown)
void setManufId(uint16_t shortaddr, const char * str);
void setModelId(uint16_t shortaddr, const char * str);
void setFriendlyName(uint16_t shortaddr, const char * str);
inline const char * getFriendlyName(uint16_t shortaddr) const {
return findShortAddr(shortaddr).friendlyName;
}
inline const char * getModelId(uint16_t shortaddr) const {
return findShortAddr(shortaddr).modelId;
}
inline const char * getManufacturerId(uint16_t shortaddr) const{
return findShortAddr(shortaddr).manufacturerId;
}
void setReachable(uint16_t shortaddr, bool reachable);
void setLQI(uint16_t shortaddr, uint8_t lqi);
void setLastSeenNow(uint16_t shortaddr);
// uint8_t getLQI(uint16_t shortaddr) const;
void setBatteryPercent(uint16_t shortaddr, uint8_t bp);
uint8_t getBatteryPercent(uint16_t shortaddr) const;
// get next sequence number for (increment at each all)
uint8_t getNextSeqNumber(uint16_t shortaddr);
// Dump json
static void addLightState(Z_attribute_list & attr_list, const Z_Data_Light & light);
String dumpLightState(uint16_t shortaddr) const;
String dump(uint32_t dump_mode, uint16_t status_shortaddr = 0) const;
int32_t deviceRestore(JsonParserObject json);
// General Zigbee device profile support
void setLightProfile(uint16_t shortaddr, uint8_t light_profile);
uint8_t getLightProfile(uint16_t shortaddr) const ;
// Hue support
int8_t getHueBulbtype(uint16_t shortaddr) const ;
void hideHueBulb(uint16_t shortaddr, bool hidden);
bool isHueBulbHidden(uint16_t shortaddr) const ;
Z_Data_Light & getLight(uint16_t shortaddr);
// Timers
void resetTimersForDevice(uint16_t shortaddr, uint16_t groupaddr, uint8_t category, uint16_t cluster = 0xFFFF, uint8_t endpoint = 0xFF);
void setTimer(uint16_t shortaddr, uint16_t groupaddr, uint32_t wait_ms, uint16_t cluster, uint8_t endpoint, uint8_t category, uint32_t value, Z_DeviceTimer func);
void queueTimer(uint16_t shortaddr, uint16_t groupaddr, uint32_t wait_ms, uint16_t cluster, uint8_t endpoint, uint8_t category, uint32_t value, Z_DeviceTimer func);
void runTimer(void);
// Append or clear attributes Json structure
void jsonAppend(uint16_t shortaddr, const Z_attribute_list &attr_list);
void jsonPublishFlush(uint16_t shortaddr); // publish the json message and clear buffer
bool jsonIsConflict(uint16_t shortaddr, const Z_attribute_list &attr_list) const;
void jsonPublishNow(uint16_t shortaddr, Z_attribute_list &attr_list);
// Iterator
size_t devicesSize(void) const {
return _devices.length();
}
const Z_Device & devicesAt(size_t i) const {
const Z_Device * devp = _devices.at(i);
if (devp) {
return *devp;
} else {
return device_unk;
}
}
// Remove device from list
bool removeDevice(uint16_t shortaddr);
// Mark data as 'dirty' and requiring to save in Flash
void dirty(void);
void clean(void); // avoid writing to flash the last changes
void shrinkToFit(uint16_t shortaddr);
// Find device by name, can be short_addr, long_addr, number_in_array or name
uint16_t parseDeviceParam(const char * param, bool short_must_be_known = false) const;
private:
LList<Z_Device> _devices; // list of devices
LList<Z_Deferred> _deferred; // list of deferred calls
uint32_t _saveTimer = 0;
uint8_t _seqNumber = 0; // global seqNumber if device is unknown
// Following device is used represent the unknown device, with all defaults
// Any find() function will not return Null, instead it will return this instance
const Z_Device device_unk = Z_Device(BAD_SHORTADDR);
//int32_t findShortAddrIdx(uint16_t shortaddr) const;
// Create a new entry in the devices list - must be called if it is sure it does not already exist
Z_Device & createDeviceEntry(uint16_t shortaddr, uint64_t longaddr = 0);
void freeDeviceEntry(Z_Device *device);
void setStringAttribute(char*& attr, const char * str);
};
/*********************************************************************************************\
* Singleton variable
\*********************************************************************************************/
Z_Devices zigbee_devices = Z_Devices();
// Local coordinator information
uint64_t localIEEEAddr = 0;
uint16_t localShortAddr = 0;
#endif // USE_ZIGBEE