Tasmota/tasmota/xdrv_23_zigbee_5_converters...

1540 lines
64 KiB
C++

/*
xdrv_23_zigbee_converters.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
/*********************************************************************************************\
* ZCL
\*********************************************************************************************/
enum Z_DataTypes {
Znodata = 0x00,
Zdata8 = 0x08, Zdata16, Zdata24, Zdata32, Zdata40, Zdata48, Zdata56, Zdata64,
Zbool = 0x10,
Zmap8 = 0x18, Zmap16, Zmap24, Zmap32, Zmap40, Zmap48, Zmap56, Zmap64,
Zuint8 = 0x20, Zuint16, Zuint24, Zuint32, Zuint40, Zuint48, Zuint56, Zuint64,
Zint8 = 0x28, Zint16, Zint24, Zint32, Zint40, Zint48, Zint56, Zint64,
Zenum8 = 0x30, Zenum16 = 0x31,
Zsemi = 0x38, Zsingle = 0x39, Zdouble = 0x3A,
Zoctstr = 0x41, Zstring = 0x42, Zoctstr16 = 0x43, Zstring16 = 0x44,
Arrray = 0x48,
Zstruct = 0x4C,
Zset = 0x50, Zbag = 0x51,
ZToD = 0xE0, Zdate = 0xE1, ZUTC = 0xE2,
ZclusterId = 0xE8, ZattribId = 0xE9, ZbacOID = 0xEA,
ZEUI64 = 0xF0, Zkey128 = 0xF1,
Zunk = 0xFF
};
//
// get the lenth in bytes for a data-type
// return 0 if unknown of type specific
//
// Note: this code is smaller than a static array
uint8_t Z_getDatatypeLen(uint8_t t) {
if ( ((t >= 0x08) && (t <= 0x0F)) || // data8 - data64
((t >= 0x18) && (t <= 0x2F)) ) { // map/uint/int
return (t & 0x07) + 1;
}
switch (t) {
case Zbool:
case Zenum8:
return 1;
case Zenum16:
case Zsemi:
case ZclusterId:
case ZattribId:
return 2;
case Zsingle:
case ZToD:
case Zdate:
case ZUTC:
case ZbacOID:
return 4;
case Zdouble:
case ZEUI64:
return 8;
case Zkey128:
return 16;
case Znodata:
default:
return 0;
}
}
// is the type a discrete type, cf. section 2.6.2 of ZCL spec
bool Z_isDiscreteDataType(uint8_t t) {
if ( ((t >= 0x20) && (t <= 0x2F)) || // uint8 - int64
((t >= 0x38) && (t <= 0x3A)) || // semi - double
((t >= 0xE0) && (t <= 0xE2)) ) { // ToD - UTC
return false;
} else {
return true;
}
}
// return value:
// 0 = keep initial value
// 1 = remove initial value
typedef int32_t (*Z_AttrConverter)(const class ZCLFrame *zcl, uint16_t shortaddr, JsonObject& json, const char *name, JsonVariant& value, const String &new_name, uint16_t cluster, uint16_t attr);
typedef struct Z_AttributeConverter {
uint8_t type;
uint8_t cluster_short;
uint16_t attribute;
uint16_t name_offset;
int8_t multiplier; // multiplier for numerical value, (if > 0 multiply by x, if <0 device by x)
uint8_t cb; // callback func from Z_ConvOperators
// Z_AttrConverter func;
} Z_AttributeConverter;
// Cluster numbers are store in 8 bits format to save space,
// the following tables allows the conversion from 8 bits index Cx...
// to the 16 bits actual cluster number
enum Cx_cluster_short {
Cx0000, Cx0001, Cx0002, Cx0003, Cx0004, Cx0005, Cx0006, Cx0007,
Cx0008, Cx0009, Cx000A, Cx000B, Cx000C, Cx000D, Cx000E, Cx000F,
Cx0010, Cx0011, Cx0012, Cx0013, Cx0014, Cx001A, Cx0020, Cx0100,
Cx0101, Cx0102, Cx0300, Cx0400, Cx0401, Cx0402, Cx0403, Cx0404,
Cx0405, Cx0406, Cx0500, Cx0B01, Cx0B05,
};
const uint16_t Cx_cluster[] PROGMEM = {
0x0000, 0x0001, 0x0002, 0x0003, 0x0004, 0x0005, 0x0006, 0x0007,
0x0008, 0x0009, 0x000A, 0x000B, 0x000C, 0x000D, 0x000E, 0x000F,
0x0010, 0x0011, 0x0012, 0x0013, 0x0014, 0x001A, 0x0020, 0x0100,
0x0101, 0x0102, 0x0300, 0x0400, 0x0401, 0x0402, 0x0403, 0x0404,
0x0405, 0x0406, 0x0500, 0x0B01, 0x0B05,
};
uint16_t CxToCluster(uint8_t cx) {
if (cx < ARRAY_SIZE(Cx_cluster)) {
return pgm_read_word(&Cx_cluster[cx]);
}
return 0xFFFF;
}
enum Z_ConvOperators {
Z_Nop, // copy value
Z_AddPressureUnit, // add pressure unit attribute (non numerical)
Z_ManufKeep, // copy and record Manufacturer attribute
Z_ModelKeep, // copy and record ModelId attribute
Z_AqaraSensor, // decode prioprietary Aqara Sensor message
Z_AqaraVibration, // decode Aqara vibration modes
Z_AqaraCube, // decode Aqara cube
Z_BatteryPercentage, // memorize Battery Percentage in RAM
};
// list of post-processing directives
const Z_AttributeConverter Z_PostProcess[] PROGMEM = {
{ Zuint8, Cx0000, 0x0000, Z_(ZCLVersion), 1, Z_Nop },
{ Zuint8, Cx0000, 0x0001, Z_(AppVersion), 1, Z_Nop },
{ Zuint8, Cx0000, 0x0002, Z_(StackVersion), 1, Z_Nop },
{ Zuint8, Cx0000, 0x0003, Z_(HWVersion), 1, Z_Nop },
{ Zstring, Cx0000, 0x0004, Z_(Manufacturer), 1, Z_ManufKeep }, // record Manufacturer
{ Zstring, Cx0000, 0x0005, Z_(ModelId), 1, Z_ModelKeep }, // record Model
{ Zstring, Cx0000, 0x0006, Z_(DateCode), 1, Z_Nop },
{ Zenum8, Cx0000, 0x0007, Z_(PowerSource), 1, Z_Nop },
{ Zenum8, Cx0000, 0x0008, Z_(GenericDeviceClass), 1, Z_Nop },
{ Zenum8, Cx0000, 0x0009, Z_(GenericDeviceType), 1, Z_Nop },
{ Zoctstr, Cx0000, 0x000A, Z_(ProductCode), 1, Z_Nop },
{ Zstring, Cx0000, 0x000B, Z_(ProductURL), 1, Z_Nop },
{ Zstring, Cx0000, 0x4000, Z_(SWBuildID), 1, Z_Nop },
// { Zunk, Cx0000, 0xFFFF, nullptr, 0, Z_Nop }, // Remove all other values
// Cmd 0x0A - Cluster 0x0000, attribute 0xFF01 - proprietary
{ Zmap8, Cx0000, 0xFF01, Z_(), 0, Z_AqaraSensor }, // Occupancy (map8)
// Power Configuration cluster
{ Zuint16, Cx0001, 0x0000, Z_(MainsVoltage), 1, Z_Nop },
{ Zuint8, Cx0001, 0x0001, Z_(MainsFrequency), 1, Z_Nop },
{ Zuint8, Cx0001, 0x0020, Z_(BatteryVoltage), -10,Z_Nop }, // divide by 10
{ Zuint8, Cx0001, 0x0021, Z_(BatteryPercentage), -2, Z_BatteryPercentage }, // divide by 2
// Device Temperature Configuration cluster
{ Zint16, Cx0002, 0x0000, Z_(CurrentTemperature), 1, Z_Nop },
{ Zint16, Cx0002, 0x0001, Z_(MinTempExperienced), 1, Z_Nop },
{ Zint16, Cx0002, 0x0002, Z_(MaxTempExperienced), 1, Z_Nop },
{ Zuint16, Cx0002, 0x0003, Z_(OverTempTotalDwell), 1, Z_Nop },
// Identify cluster
{ Zuint16, Cx0003, 0x0000, Z_(IdentifyTime), 1, Z_Nop },
// Groups cluster
{ Zmap8, Cx0004, 0x0000, Z_(GroupNameSupport), 1, Z_Nop },
// Scenes cluster
{ Zuint8, Cx0005, 0x0000, Z_(SceneCount), 1, Z_Nop },
{ Zuint8, Cx0005, 0x0001, Z_(CurrentScene), 1, Z_Nop },
{ Zuint16, Cx0005, 0x0002, Z_(CurrentGroup), 1, Z_Nop },
{ Zbool, Cx0005, 0x0003, Z_(SceneValid), 1, Z_Nop },
//{ Zmap8, Cx0005, 0x0004, Z_(NameSupport), 1, Z_Nop },
// On/off cluster
{ Zbool, Cx0006, 0x0000, Z_(Power), 1, Z_Nop },
{ Zenum8, Cx0006, 0x4003, Z_(StartUpOnOff), 1, Z_Nop },
{ Zbool, Cx0006, 0x8000, Z_(Power), 1, Z_Nop }, // See 7280
// On/Off Switch Configuration cluster
{ Zenum8, Cx0007, 0x0000, Z_(SwitchType), 1, Z_Nop },
// Level Control cluster
{ Zuint8, Cx0008, 0x0000, Z_(Dimmer), 1, Z_Nop },
{ Zmap8, Cx0008, 0x000F, Z_(DimmerOptions), 1, Z_Nop },
{ Zuint16, Cx0008, 0x0001, Z_(DimmerRemainingTime), 1, Z_Nop },
{ Zuint16, Cx0008, 0x0010, Z_(OnOffTransitionTime), 1, Z_Nop },
// { Zuint8, Cx0008, 0x0011, Z_(OnLevel), 1, Z_Nop },
// { Zuint16, Cx0008, 0x0012, Z_(OnTransitionTime), 1, Z_Nop },
// { Zuint16, Cx0008, 0x0013, Z_(OffTransitionTime), 1, Z_Nop },
// { Zuint16, Cx0008, 0x0014, Z_(DefaultMoveRate), 1, Z_Nop },
// Alarms cluster
{ Zuint16, Cx0009, 0x0000, Z_(AlarmCount), 1, Z_Nop },
// Time cluster
{ ZUTC, Cx000A, 0x0000, Z_(Time), 1, Z_Nop },
{ Zmap8, Cx000A, 0x0001, Z_(TimeStatus), 1, Z_Nop },
{ Zint32, Cx000A, 0x0002, Z_(TimeZone), 1, Z_Nop },
{ Zuint32, Cx000A, 0x0003, Z_(DstStart), 1, Z_Nop },
{ Zuint32, Cx000A, 0x0004, Z_(DstEnd), 1, Z_Nop },
{ Zint32, Cx000A, 0x0005, Z_(DstShift), 1, Z_Nop },
{ Zuint32, Cx000A, 0x0006, Z_(StandardTime), 1, Z_Nop },
{ Zuint32, Cx000A, 0x0007, Z_(LocalTime), 1, Z_Nop },
{ ZUTC, Cx000A, 0x0008, Z_(LastSetTime), 1, Z_Nop },
{ ZUTC, Cx000A, 0x0009, Z_(ValidUntilTime), 1, Z_Nop },
{ ZUTC, Cx000A, 0xFF00, Z_(TimeEpoch), 1, Z_Nop }, // Tasmota specific, epoch
// RSSI Location cluster
{ Zdata8, Cx000B, 0x0000, Z_(LocationType), 1, Z_Nop },
{ Zenum8, Cx000B, 0x0001, Z_(LocationMethod), 1, Z_Nop },
{ Zuint16, Cx000B, 0x0002, Z_(LocationAge), 1, Z_Nop },
{ Zuint8, Cx000B, 0x0003, Z_(QualityMeasure), 1, Z_Nop },
{ Zuint8, Cx000B, 0x0004, Z_(NumberOfDevices), 1, Z_Nop },
// Analog Input cluster
// { 0xFF, Cx000C, 0x0004, Z_(AnalogInActiveText), 1, Z_Nop },
{ Zstring, Cx000C, 0x001C, Z_(AnalogInDescription), 1, Z_Nop },
// { 0xFF, Cx000C, 0x002E, Z_(AnalogInInactiveText), 1, Z_Nop },
{ Zsingle, Cx000C, 0x0041, Z_(AnalogInMaxValue), 1, Z_Nop },
{ Zsingle, Cx000C, 0x0045, Z_(AnalogInMinValue), 1, Z_Nop },
{ Zbool, Cx000C, 0x0051, Z_(AnalogInOutOfService), 1, Z_Nop },
{ Zsingle, Cx000C, 0x0055, Z_(AqaraRotate), 1, Z_Nop },
// { 0xFF, Cx000C, 0x0057, Z_(AnalogInPriorityArray),1, Z_Nop },
{ Zenum8, Cx000C, 0x0067, Z_(AnalogInReliability), 1, Z_Nop },
// { 0xFF, Cx000C, 0x0068, Z_(AnalogInRelinquishDefault),1, Z_Nop },
{ Zsingle, Cx000C, 0x006A, Z_(AnalogInResolution), 1, Z_Nop },
{ Zmap8, Cx000C, 0x006F, Z_(AnalogInStatusFlags), 1, Z_Nop },
{ Zenum16, Cx000C, 0x0075, Z_(AnalogInEngineeringUnits),1, Z_Nop },
{ Zuint32, Cx000C, 0x0100, Z_(AnalogInApplicationType),1, Z_Nop },
{ Zuint16, Cx000C, 0xFF05, Z_(Aqara_FF05), 1, Z_Nop },
// Analog Output cluster
{ Zstring, Cx000D, 0x001C, Z_(AnalogOutDescription), 1, Z_Nop },
{ Zsingle, Cx000D, 0x0041, Z_(AnalogOutMaxValue), 1, Z_Nop },
{ Zsingle, Cx000D, 0x0045, Z_(AnalogOutMinValue), 1, Z_Nop },
{ Zbool, Cx000D, 0x0051, Z_(AnalogOutOutOfService),1, Z_Nop },
{ Zsingle, Cx000D, 0x0055, Z_(AnalogOutValue), 1, Z_Nop },
// { Zunk, Cx000D, 0x0057, Z_(AnalogOutPriorityArray),1, Z_Nop },
{ Zenum8, Cx000D, 0x0067, Z_(AnalogOutReliability), 1, Z_Nop },
{ Zsingle, Cx000D, 0x0068, Z_(AnalogOutRelinquishDefault),1, Z_Nop },
{ Zsingle, Cx000D, 0x006A, Z_(AnalogOutResolution), 1, Z_Nop },
{ Zmap8, Cx000D, 0x006F, Z_(AnalogOutStatusFlags), 1, Z_Nop },
{ Zenum16, Cx000D, 0x0075, Z_(AnalogOutEngineeringUnits),1, Z_Nop },
{ Zuint32, Cx000D, 0x0100, Z_(AnalogOutApplicationType),1, Z_Nop },
// Analog Value cluster
{ Zstring, Cx000E, 0x001C, Z_(AnalogDescription), 1, Z_Nop },
{ Zbool, Cx000E, 0x0051, Z_(AnalogOutOfService), 1, Z_Nop },
{ Zsingle, Cx000E, 0x0055, Z_(AnalogValue), 1, Z_Nop },
{ Zunk, Cx000E, 0x0057, Z_(AnalogPriorityArray), 1, Z_Nop },
{ Zenum8, Cx000E, 0x0067, Z_(AnalogReliability), 1, Z_Nop },
{ Zsingle, Cx000E, 0x0068, Z_(AnalogRelinquishDefault),1, Z_Nop },
{ Zmap8, Cx000E, 0x006F, Z_(AnalogStatusFlags), 1, Z_Nop },
{ Zenum16, Cx000E, 0x0075, Z_(AnalogEngineeringUnits),1, Z_Nop },
{ Zuint32, Cx000E, 0x0100, Z_(AnalogApplicationType),1, Z_Nop },
// Binary Input cluster
{ Zstring, Cx000F, 0x0004, Z_(BinaryInActiveText), 1, Z_Nop },
{ Zstring, Cx000F, 0x001C, Z_(BinaryInDescription), 1, Z_Nop },
{ Zstring, Cx000F, 0x002E, Z_(BinaryInInactiveText),1, Z_Nop },
{ Zbool, Cx000F, 0x0051, Z_(BinaryInOutOfService),1, Z_Nop },
{ Zenum8, Cx000F, 0x0054, Z_(BinaryInPolarity), 1, Z_Nop },
{ Zstring, Cx000F, 0x0055, Z_(BinaryInValue), 1, Z_Nop },
// { 0xFF, Cx000F, 0x0057, Z_(BinaryInPriorityArray),1, Z_Nop },
{ Zenum8, Cx000F, 0x0067, Z_(BinaryInReliability), 1, Z_Nop },
{ Zmap8, Cx000F, 0x006F, Z_(BinaryInStatusFlags), 1, Z_Nop },
{ Zuint32, Cx000F, 0x0100, Z_(BinaryInApplicationType),1, Z_Nop },
// Binary Output cluster
{ Zstring, Cx0010, 0x0004, Z_(BinaryOutActiveText), 1, Z_Nop },
{ Zstring, Cx0010, 0x001C, Z_(BinaryOutDescription), 1, Z_Nop },
{ Zstring, Cx0010, 0x002E, Z_(BinaryOutInactiveText),1, Z_Nop },
{ Zuint32, Cx0010, 0x0042, Z_(BinaryOutMinimumOffTime),1, Z_Nop },
{ Zuint32, Cx0010, 0x0043, Z_(BinaryOutMinimumOnTime),1, Z_Nop },
{ Zbool, Cx0010, 0x0051, Z_(BinaryOutOutOfService),1, Z_Nop },
{ Zenum8, Cx0010, 0x0054, Z_(BinaryOutPolarity), 1, Z_Nop },
{ Zbool, Cx0010, 0x0055, Z_(BinaryOutValue), 1, Z_Nop },
// { Zunk, Cx0010, 0x0057, Z_(BinaryOutPriorityArray),1, Z_Nop },
{ Zenum8, Cx0010, 0x0067, Z_(BinaryOutReliability), 1, Z_Nop },
{ Zbool, Cx0010, 0x0068, Z_(BinaryOutRelinquishDefault),1, Z_Nop },
{ Zmap8, Cx0010, 0x006F, Z_(BinaryOutStatusFlags), 1, Z_Nop },
{ Zuint32, Cx0010, 0x0100, Z_(BinaryOutApplicationType),1, Z_Nop },
// Binary Value cluster
{ Zstring, Cx0011, 0x0004, Z_(BinaryActiveText), 1, Z_Nop },
{ Zstring, Cx0011, 0x001C, Z_(BinaryDescription), 1, Z_Nop },
{ Zstring, Cx0011, 0x002E, Z_(BinaryInactiveText), 1, Z_Nop },
{ Zuint32, Cx0011, 0x0042, Z_(BinaryMinimumOffTime), 1, Z_Nop },
{ Zuint32, Cx0011, 0x0043, Z_(BinaryMinimumOnTime), 1, Z_Nop },
{ Zbool, Cx0011, 0x0051, Z_(BinaryOutOfService), 1, Z_Nop },
{ Zbool, Cx0011, 0x0055, Z_(BinaryValue), 1, Z_Nop },
// { Zunk, Cx0011, 0x0057, Z_(BinaryPriorityArray), 1, Z_Nop },
{ Zenum8, Cx0011, 0x0067, Z_(BinaryReliability), 1, Z_Nop },
{ Zbool, Cx0011, 0x0068, Z_(BinaryRelinquishDefault),1, Z_Nop },
{ Zmap8, Cx0011, 0x006F, Z_(BinaryStatusFlags), 1, Z_Nop },
{ Zuint32, Cx0011, 0x0100, Z_(BinaryApplicationType),1, Z_Nop },
// Multistate Input cluster
// { Zunk, Cx0012, 0x000E, Z_(MultiInStateText), 1, Z_Nop },
{ Zstring, Cx0012, 0x001C, Z_(MultiInDescription), 1, Z_Nop },
{ Zuint16, Cx0012, 0x004A, Z_(MultiInNumberOfStates),1, Z_Nop },
{ Zbool, Cx0012, 0x0051, Z_(MultiInOutOfService), 1, Z_Nop },
{ Zuint16, Cx0012, 0x0055, Z_(MultiInValue), 0, Z_AqaraCube },
{ Zenum8, Cx0012, 0x0067, Z_(MultiInReliability), 1, Z_Nop },
{ Zmap8, Cx0012, 0x006F, Z_(MultiInStatusFlags), 1, Z_Nop },
{ Zuint32, Cx0012, 0x0100, Z_(MultiInApplicationType),1, Z_Nop },
// Multistate output
// { Zunk, Cx0013, 0x000E, Z_(MultiOutStateText), 1, Z_Nop },
{ Zstring, Cx0013, 0x001C, Z_(MultiOutDescription), 1, Z_Nop },
{ Zuint16, Cx0013, 0x004A, Z_(MultiOutNumberOfStates),1, Z_Nop },
{ Zbool, Cx0013, 0x0051, Z_(MultiOutOutOfService), 1, Z_Nop },
{ Zuint16, Cx0013, 0x0055, Z_(MultiOutValue), 1, Z_Nop },
// { Zunk, Cx0013, 0x0057, Z_(MultiOutPriorityArray),1, Z_Nop },
{ Zenum8, Cx0013, 0x0067, Z_(MultiOutReliability), 1, Z_Nop },
{ Zuint16, Cx0013, 0x0068, Z_(MultiOutRelinquishDefault),1, Z_Nop },
{ Zmap8, Cx0013, 0x006F, Z_(MultiOutStatusFlags), 1, Z_Nop },
{ Zuint32, Cx0013, 0x0100, Z_(MultiOutApplicationType),1, Z_Nop },
// Multistate Value cluster
// { Zunk, Cx0014, 0x000E, Z_(MultiStateText), 1, Z_Nop },
{ Zstring, Cx0014, 0x001C, Z_(MultiDescription), 1, Z_Nop },
{ Zuint16, Cx0014, 0x004A, Z_(MultiNumberOfStates), 1, Z_Nop },
{ Zbool, Cx0014, 0x0051, Z_(MultiOutOfService), 1, Z_Nop },
{ Zuint16, Cx0014, 0x0055, Z_(MultiValue), 1, Z_Nop },
{ Zenum8, Cx0014, 0x0067, Z_(MultiReliability), 1, Z_Nop },
{ Zuint16, Cx0014, 0x0068, Z_(MultiRelinquishDefault),1, Z_Nop },
{ Zmap8, Cx0014, 0x006F, Z_(MultiStatusFlags), 1, Z_Nop },
{ Zuint32, Cx0014, 0x0100, Z_(MultiApplicationType), 1, Z_Nop },
// Power Profile cluster
{ Zuint8, Cx001A, 0x0000, Z_(TotalProfileNum), 1, Z_Nop },
{ Zbool, Cx001A, 0x0001, Z_(MultipleScheduling), 1, Z_Nop },
{ Zmap8, Cx001A, 0x0002, Z_(EnergyFormatting), 1, Z_Nop },
{ Zbool, Cx001A, 0x0003, Z_(EnergyRemote), 1, Z_Nop },
{ Zmap8, Cx001A, 0x0004, Z_(ScheduleMode), 1, Z_Nop },
// Poll Control cluster
{ Zuint32, Cx0020, 0x0000, Z_(CheckinInterval), 1, Z_Nop },
{ Zuint32, Cx0020, 0x0001, Z_(LongPollInterval), 1, Z_Nop },
{ Zuint16, Cx0020, 0x0002, Z_(ShortPollInterval), 1, Z_Nop },
{ Zuint16, Cx0020, 0x0003, Z_(FastPollTimeout), 1, Z_Nop },
{ Zuint32, Cx0020, 0x0004, Z_(CheckinIntervalMin), 1, Z_Nop },
{ Zuint32, Cx0020, 0x0005, Z_(LongPollIntervalMin), 1, Z_Nop },
{ Zuint16, Cx0020, 0x0006, Z_(FastPollTimeoutMax), 1, Z_Nop },
// Shade Configuration cluster
{ Zuint16, Cx0100, 0x0000, Z_(PhysicalClosedLimit), 1, Z_Nop },
{ Zuint8, Cx0100, 0x0001, Z_(MotorStepSize), 1, Z_Nop },
{ Zmap8, Cx0100, 0x0002, Z_(Status), 1, Z_Nop },
{ Zuint16, Cx0100, 0x0010, Z_(ClosedLimit), 1, Z_Nop },
{ Zenum8, Cx0100, 0x0011, Z_(Mode), 1, Z_Nop },
// Door Lock cluster
{ Zenum8, Cx0101, 0x0000, Z_(LockState), 1, Z_Nop },
{ Zenum8, Cx0101, 0x0001, Z_(LockType), 1, Z_Nop },
{ Zbool, Cx0101, 0x0002, Z_(ActuatorEnabled), 1, Z_Nop },
{ Zenum8, Cx0101, 0x0003, Z_(DoorState), 1, Z_Nop },
{ Zuint32, Cx0101, 0x0004, Z_(DoorOpenEvents), 1, Z_Nop },
{ Zuint32, Cx0101, 0x0005, Z_(DoorClosedEvents), 1, Z_Nop },
{ Zuint16, Cx0101, 0x0006, Z_(OpenPeriod), 1, Z_Nop },
// Aqara Lumi Vibration Sensor
{ Zuint16, Cx0101, 0x0055, Z_(AqaraVibrationMode), 0, Z_AqaraVibration },
{ Zuint16, Cx0101, 0x0503, Z_(AqaraVibrationsOrAngle), 1, Z_Nop },
{ Zuint32, Cx0101, 0x0505, Z_(AqaraVibration505), 1, Z_Nop },
{ Zuint48, Cx0101, 0x0508, Z_(AqaraAccelerometer), 0, Z_AqaraVibration },
// Window Covering cluster
{ Zenum8, Cx0102, 0x0000, Z_(WindowCoveringType), 1, Z_Nop },
{ Zuint16, Cx0102, 0x0001, Z_(PhysicalClosedLimitLift),1, Z_Nop },
{ Zuint16, Cx0102, 0x0002, Z_(PhysicalClosedLimitTilt),1, Z_Nop },
{ Zuint16, Cx0102, 0x0003, Z_(CurrentPositionLift), 1, Z_Nop },
{ Zuint16, Cx0102, 0x0004, Z_(CurrentPositionTilt), 1, Z_Nop },
{ Zuint16, Cx0102, 0x0005, Z_(NumberofActuationsLift),1, Z_Nop },
{ Zuint16, Cx0102, 0x0006, Z_(NumberofActuationsTilt),1, Z_Nop },
{ Zmap8, Cx0102, 0x0007, Z_(ConfigStatus), 1, Z_Nop },
{ Zuint8, Cx0102, 0x0008, Z_(CurrentPositionLiftPercentage),1, Z_Nop },
{ Zuint8, Cx0102, 0x0009, Z_(CurrentPositionTiltPercentage),1, Z_Nop },
{ Zuint16, Cx0102, 0x0010, Z_(InstalledOpenLimitLift),1, Z_Nop },
{ Zuint16, Cx0102, 0x0011, Z_(InstalledClosedLimitLift),1, Z_Nop },
{ Zuint16, Cx0102, 0x0012, Z_(InstalledOpenLimitTilt),1, Z_Nop },
{ Zuint16, Cx0102, 0x0013, Z_(InstalledClosedLimitTilt),1, Z_Nop },
{ Zuint16, Cx0102, 0x0014, Z_(VelocityLift), 1, Z_Nop },
{ Zuint16, Cx0102, 0x0015, Z_(AccelerationTimeLift),1, Z_Nop },
{ Zuint16, Cx0102, 0x0016, Z_(DecelerationTimeLift), 1, Z_Nop },
{ Zmap8, Cx0102, 0x0017, Z_(Mode), 1, Z_Nop },
{ Zoctstr, Cx0102, 0x0018, Z_(IntermediateSetpointsLift),1, Z_Nop },
{ Zoctstr, Cx0102, 0x0019, Z_(IntermediateSetpointsTilt),1, Z_Nop },
// Color Control cluster
{ Zuint8, Cx0300, 0x0000, Z_(Hue), 1, Z_Nop },
{ Zuint8, Cx0300, 0x0001, Z_(Sat), 1, Z_Nop },
{ Zuint16, Cx0300, 0x0002, Z_(RemainingTime), 1, Z_Nop },
{ Zuint16, Cx0300, 0x0003, Z_(X), 1, Z_Nop },
{ Zuint16, Cx0300, 0x0004, Z_(Y), 1, Z_Nop },
{ Zenum8, Cx0300, 0x0005, Z_(DriftCompensation), 1, Z_Nop },
{ Zstring, Cx0300, 0x0006, Z_(CompensationText), 1, Z_Nop },
{ Zuint16, Cx0300, 0x0007, Z_(CT), 1, Z_Nop },
{ Zenum8, Cx0300, 0x0008, Z_(ColorMode), 1, Z_Nop },
{ Zuint8, Cx0300, 0x0010, Z_(NumberOfPrimaries), 1, Z_Nop },
{ Zuint16, Cx0300, 0x0011, Z_(Primary1X), 1, Z_Nop },
{ Zuint16, Cx0300, 0x0012, Z_(Primary1Y), 1, Z_Nop },
{ Zuint8, Cx0300, 0x0013, Z_(Primary1Intensity), 1, Z_Nop },
{ Zuint16, Cx0300, 0x0015, Z_(Primary2X), 1, Z_Nop },
{ Zuint16, Cx0300, 0x0016, Z_(Primary2Y), 1, Z_Nop },
{ Zuint8, Cx0300, 0x0017, Z_(Primary2Intensity), 1, Z_Nop },
{ Zuint16, Cx0300, 0x0019, Z_(Primary3X), 1, Z_Nop },
{ Zuint16, Cx0300, 0x001A, Z_(Primary3Y), 1, Z_Nop },
{ Zuint8, Cx0300, 0x001B, Z_(Primary3Intensity), 1, Z_Nop },
{ Zuint16, Cx0300, 0x0030, Z_(WhitePointX), 1, Z_Nop },
{ Zuint16, Cx0300, 0x0031, Z_(WhitePointY), 1, Z_Nop },
{ Zuint16, Cx0300, 0x0032, Z_(ColorPointRX), 1, Z_Nop },
{ Zuint16, Cx0300, 0x0033, Z_(ColorPointRY), 1, Z_Nop },
{ Zuint8, Cx0300, 0x0034, Z_(ColorPointRIntensity), 1, Z_Nop },
{ Zuint16, Cx0300, 0x0036, Z_(ColorPointGX), 1, Z_Nop },
{ Zuint16, Cx0300, 0x0037, Z_(ColorPointGY), 1, Z_Nop },
{ Zuint8, Cx0300, 0x0038, Z_(ColorPointGIntensity), 1, Z_Nop },
{ Zuint16, Cx0300, 0x003A, Z_(ColorPointBX), 1, Z_Nop },
{ Zuint16, Cx0300, 0x003B, Z_(ColorPointBY), 1, Z_Nop },
{ Zuint8, Cx0300, 0x003C, Z_(ColorPointBIntensity), 1, Z_Nop },
// Illuminance Measurement cluster
{ Zuint16, Cx0400, 0x0000, Z_(Illuminance), 1, Z_Nop }, // Illuminance (in Lux)
{ Zuint16, Cx0400, 0x0001, Z_(IlluminanceMinMeasuredValue), 1, Z_Nop }, //
{ Zuint16, Cx0400, 0x0002, Z_(IlluminanceMaxMeasuredValue), 1, Z_Nop }, //
{ Zuint16, Cx0400, 0x0003, Z_(IlluminanceTolerance), 1, Z_Nop }, //
{ Zenum8, Cx0400, 0x0004, Z_(IlluminanceLightSensorType), 1, Z_Nop }, //
{ Zunk, Cx0400, 0xFFFF, Z_(), 0, Z_Nop }, // Remove all other values
// Illuminance Level Sensing cluster
{ Zenum8, Cx0401, 0x0000, Z_(IlluminanceLevelStatus), 1, Z_Nop }, // Illuminance (in Lux)
{ Zenum8, Cx0401, 0x0001, Z_(IlluminanceLightSensorType), 1, Z_Nop }, // LightSensorType
{ Zuint16, Cx0401, 0x0010, Z_(IlluminanceTargetLevel), 1, Z_Nop }, //
{ Zunk, Cx0401, 0xFFFF, Z_(), 0, Z_Nop }, // Remove all other values
// Temperature Measurement cluster
{ Zint16, Cx0402, 0x0000, Z_(Temperature), -100, Z_Nop }, // divide by 100
{ Zint16, Cx0402, 0x0001, Z_(TemperatureMinMeasuredValue), -100, Z_Nop }, //
{ Zint16, Cx0402, 0x0002, Z_(TemperatureMaxMeasuredValue), -100, Z_Nop }, //
{ Zuint16, Cx0402, 0x0003, Z_(TemperatureTolerance), -100, Z_Nop }, //
{ Zunk, Cx0402, 0xFFFF, Z_(), 0, Z_Nop }, // Remove all other values
// Pressure Measurement cluster
{ Zunk, Cx0403, 0x0000, Z_(PressureUnit), 0, Z_AddPressureUnit }, // Pressure Unit
{ Zint16, Cx0403, 0x0000, Z_(Pressure), 1, Z_Nop }, // Pressure
{ Zint16, Cx0403, 0x0001, Z_(PressureMinMeasuredValue), 1, Z_Nop }, //
{ Zint16, Cx0403, 0x0002, Z_(PressureMaxMeasuredValue), 1, Z_Nop }, //
{ Zuint16, Cx0403, 0x0003, Z_(PressureTolerance), 1, Z_Nop }, //
{ Zint16, Cx0403, 0x0010, Z_(PressureScaledValue), 1, Z_Nop }, //
{ Zint16, Cx0403, 0x0011, Z_(PressureMinScaledValue), 1, Z_Nop }, //
{ Zint16, Cx0403, 0x0012, Z_(PressureMaxScaledValue), 1, Z_Nop }, //
{ Zuint16, Cx0403, 0x0013, Z_(PressureScaledTolerance), 1, Z_Nop }, //
{ Zint8, Cx0403, 0x0014, Z_(PressureScale), 1, Z_Nop }, //
{ Zunk, Cx0403, 0xFFFF, Z_(), 0, Z_Nop }, // Remove all other Pressure values
// Flow Measurement cluster
{ Zuint16, Cx0404, 0x0000, Z_(FlowRate), -10, Z_Nop }, // Flow (in m3/h)
{ Zuint16, Cx0404, 0x0001, Z_(FlowMinMeasuredValue), 1, Z_Nop }, //
{ Zuint16, Cx0404, 0x0002, Z_(FlowMaxMeasuredValue), 1, Z_Nop }, //
{ Zuint16, Cx0404, 0x0003, Z_(FlowTolerance), 1, Z_Nop }, //
{ Zunk, Cx0404, 0xFFFF, Z_(), 0, Z_Nop }, // Remove all other values
// Relative Humidity Measurement cluster
{ Zuint16, Cx0405, 0x0000, Z_(Humidity), -100, Z_Nop }, // Humidity
{ Zuint16, Cx0405, 0x0001, Z_(HumidityMinMeasuredValue), 1, Z_Nop }, //
{ Zuint16, Cx0405, 0x0002, Z_(HumidityMaxMeasuredValue), 1, Z_Nop }, //
{ Zuint16, Cx0405, 0x0003, Z_(HumidityTolerance), 1, Z_Nop }, //
{ Zunk, Cx0405, 0xFFFF, Z_(), 0, Z_Nop }, // Remove all other values
// Occupancy Sensing cluster
{ Zmap8, Cx0406, 0x0000, Z_(Occupancy), 1, Z_Nop }, // Occupancy (map8)
{ Zenum8, Cx0406, 0x0001, Z_(OccupancySensorType), 1, Z_Nop }, // OccupancySensorType
{ Zunk, Cx0406, 0xFFFF, Z_(), 0, Z_Nop }, // Remove all other values
// IAS Cluster (Intruder Alarm System)
{ Zenum8, Cx0500, 0x0000, Z_(ZoneState), 1, Z_Nop }, // Occupancy (map8)
{ Zenum16, Cx0500, 0x0001, Z_(ZoneType), 1, Z_Nop }, // Occupancy (map8)
{ Zmap16, Cx0500, 0x0002, Z_(ZoneStatus), 1, Z_Nop }, // Occupancy (map8)
// Meter Identification cluster
{ Zstring, Cx0B01, 0x0000, Z_(CompanyName), 1, Z_Nop },
{ Zuint16, Cx0B01, 0x0001, Z_(MeterTypeID), 1, Z_Nop },
{ Zuint16, Cx0B01, 0x0004, Z_(DataQualityID), 1, Z_Nop },
{ Zstring, Cx0B01, 0x0005, Z_(CustomerName), 1, Z_Nop },
{ Zoctstr, Cx0B01, 0x0006, Z_(Model), 1, Z_Nop },
{ Zoctstr, Cx0B01, 0x0007, Z_(PartNumber), 1, Z_Nop },
{ Zoctstr, Cx0B01, 0x0008, Z_(ProductRevision), 1, Z_Nop },
{ Zoctstr, Cx0B01, 0x000A, Z_(SoftwareRevision), 1, Z_Nop },
{ Zstring, Cx0B01, 0x000B, Z_(UtilityName), 1, Z_Nop },
{ Zstring, Cx0B01, 0x000C, Z_(POD), 1, Z_Nop },
{ Zint24, Cx0B01, 0x000D, Z_(AvailablePower), 1, Z_Nop },
{ Zint24, Cx0B01, 0x000E, Z_(PowerThreshold), 1, Z_Nop },
// Diagnostics cluster
{ Zuint16, Cx0B05, 0x0000, Z_(NumberOfResets), 1, Z_Nop },
{ Zuint16, Cx0B05, 0x0001, Z_(PersistentMemoryWrites),1, Z_Nop },
{ Zuint8, Cx0B05, 0x011C, Z_(LastMessageLQI), 1, Z_Nop },
{ Zuint8, Cx0B05, 0x011D, Z_(LastMessageRSSI), 1, Z_Nop },
};
typedef union ZCLHeaderFrameControl_t {
struct {
uint8_t frame_type : 2; // 00 = across entire profile, 01 = cluster specific
uint8_t manuf_specific : 1; // Manufacturer Specific Sub-field
uint8_t direction : 1; // 0 = tasmota to zigbee, 1 = zigbee to tasmota
uint8_t disable_def_resp : 1; // don't send back default response
uint8_t reserved : 3;
} b;
uint32_t d8; // raw 8 bits field
} ZCLHeaderFrameControl_t;
// Find the attribute details by attribute name
// If not found:
// - returns nullptr
const __FlashStringHelper* zigbeeFindAttributeByName(const char *command,
uint16_t *cluster, uint16_t *attribute, int8_t *multiplier,
uint8_t *cb) {
for (uint32_t i = 0; i < ARRAY_SIZE(Z_PostProcess); i++) {
const Z_AttributeConverter *converter = &Z_PostProcess[i];
if (0 == pgm_read_word(&converter->name_offset)) { continue; } // avoid strcasecmp_P() from crashing
if (0 == strcasecmp_P(command, Z_strings + pgm_read_word(&converter->name_offset))) {
if (cluster) { *cluster = CxToCluster(pgm_read_byte(&converter->cluster_short)); }
if (attribute) { *attribute = pgm_read_word(&converter->attribute); }
if (multiplier) { *multiplier = pgm_read_byte(&converter->multiplier); }
if (cb) { *cb = pgm_read_byte(&converter->cb); }
return (const __FlashStringHelper*) (Z_strings + pgm_read_word(&converter->name_offset));
}
}
return nullptr;
}
class ZCLFrame {
public:
ZCLFrame(uint8_t frame_control, uint16_t manuf_code, uint8_t transact_seq, uint8_t cmd_id,
const char *buf, size_t buf_len, uint16_t clusterid, uint16_t groupaddr,
uint16_t srcaddr, uint8_t srcendpoint, uint8_t dstendpoint, uint8_t wasbroadcast,
uint8_t linkquality, uint8_t securityuse, uint8_t seqnumber):
_manuf_code(manuf_code), _transact_seq(transact_seq), _cmd_id(cmd_id),
_payload(buf_len ? buf_len : 250), // allocate the data frame from source or preallocate big enough
_cluster_id(clusterid), _groupaddr(groupaddr),
_srcaddr(srcaddr), _srcendpoint(srcendpoint), _dstendpoint(dstendpoint), _wasbroadcast(wasbroadcast),
_linkquality(linkquality), _securityuse(securityuse), _seqnumber(seqnumber)
{
_frame_control.d8 = frame_control;
_payload.addBuffer(buf, buf_len);
};
void log(void) {
char hex_char[_payload.len()*2+2];
ToHex_P((unsigned char*)_payload.getBuffer(), _payload.len(), hex_char, sizeof(hex_char));
Response_P(PSTR("{\"" D_JSON_ZIGBEEZCL_RECEIVED "\":{"
"\"groupid\":%d," "\"clusterid\":%d," "\"srcaddr\":\"0x%04X\","
"\"srcendpoint\":%d," "\"dstendpoint\":%d," "\"wasbroadcast\":%d,"
"\"" D_CMND_ZIGBEE_LINKQUALITY "\":%d," "\"securityuse\":%d," "\"seqnumber\":%d,"
"\"fc\":\"0x%02X\",\"manuf\":\"0x%04X\",\"transact\":%d,"
"\"cmdid\":\"0x%02X\",\"payload\":\"%s\"}}"),
_groupaddr, _cluster_id, _srcaddr,
_srcendpoint, _dstendpoint, _wasbroadcast,
_linkquality, _securityuse, _seqnumber,
_frame_control, _manuf_code, _transact_seq, _cmd_id,
hex_char);
if (Settings.flag3.tuya_serial_mqtt_publish) {
MqttPublishPrefixTopicRulesProcess_P(TELE, PSTR(D_RSLT_SENSOR));
} else {
AddLog_P2(LOG_LEVEL_DEBUG, PSTR(D_LOG_ZIGBEE "%s"), mqtt_data);
}
}
static ZCLFrame parseRawFrame(const SBuffer &buf, uint8_t offset, uint8_t len, uint16_t clusterid, uint16_t groupid,
uint16_t srcaddr, uint8_t srcendpoint, uint8_t dstendpoint, uint8_t wasbroadcast,
uint8_t linkquality, uint8_t securityuse, uint8_t seqnumber) { // parse a raw frame and build the ZCL frame object
uint32_t i = offset;
ZCLHeaderFrameControl_t frame_control;
uint16_t manuf_code = 0;
uint8_t transact_seq;
uint8_t cmd_id;
frame_control.d8 = buf.get8(i++);
if (frame_control.b.manuf_specific) {
manuf_code = buf.get16(i);
i += 2;
}
transact_seq = buf.get8(i++);
cmd_id = buf.get8(i++);
ZCLFrame zcl_frame(frame_control.d8, manuf_code, transact_seq, cmd_id,
(const char *)(buf.buf() + i), len + offset - i,
clusterid, groupid,
srcaddr, srcendpoint, dstendpoint, wasbroadcast,
linkquality, securityuse, seqnumber);
return zcl_frame;
}
bool isClusterSpecificCommand(void) {
return _frame_control.b.frame_type & 1;
}
static void generateAttributeName(const JsonObject& json, uint16_t cluster, uint16_t attr, char *key, size_t key_len);
void parseReportAttributes(JsonObject& json, uint8_t offset = 0);
void parseReadAttributes(JsonObject& json, uint8_t offset = 0);
void parseReadAttributesResponse(JsonObject& json, uint8_t offset = 0);
void parseReadConfigAttributes(JsonObject& json, uint8_t offset = 0);
void parseConfigAttributes(JsonObject& json, uint8_t offset = 0);
void parseResponse(void);
void parseClusterSpecificCommand(JsonObject& json, uint8_t offset = 0);
void postProcessAttributes(uint16_t shortaddr, JsonObject& json);
inline void setGroupId(uint16_t groupid) {
_groupaddr = groupid;
}
inline void setClusterId(uint16_t clusterid) {
_cluster_id = clusterid;
}
inline uint16_t getSrcAddr(void) const { return _srcaddr; }
inline uint16_t getGroupAddr(void) const { return _groupaddr; }
inline uint16_t getClusterId(void) const { return _cluster_id; }
inline uint8_t getLinkQuality(void) const { return _linkquality; }
inline uint8_t getCmdId(void) const { return _cmd_id; }
inline uint16_t getSrcEndpoint(void) const { return _srcendpoint; }
const SBuffer &getPayload(void) const {
return _payload;
}
uint16_t getManufCode(void) const {
return _manuf_code;
}
private:
ZCLHeaderFrameControl_t _frame_control = { .d8 = 0 };
uint16_t _manuf_code = 0; // optional
uint8_t _transact_seq = 0; // transaction sequence number
uint8_t _cmd_id = 0;
SBuffer _payload;
uint16_t _cluster_id = 0;
uint16_t _groupaddr = 0;
// information from decoded ZCL frame
uint16_t _srcaddr;
uint8_t _srcendpoint;
uint8_t _dstendpoint;
uint8_t _wasbroadcast;
uint8_t _linkquality;
uint8_t _securityuse;
uint8_t _seqnumber;
};
// Zigbee ZCL converters
// from https://github.com/Koenkk/zigbee-shepherd-converters/blob/638d29f0cace6343052b9a4e7fd60980fa785479/converters/fromZigbee.js#L55
// Input voltage in mV, i.e. 3000 = 3.000V
// Output percentage from 0 to 100 as int
uint8_t toPercentageCR2032(uint32_t voltage) {
uint32_t percentage;
if (voltage < 2100) {
percentage = 0;
} else if (voltage < 2440) {
percentage = 6 - ((2440 - voltage) * 6) / 340;
} else if (voltage < 2740) {
percentage = 18 - ((2740 - voltage) * 12) / 300;
} else if (voltage < 2900) {
percentage = 42 - ((2900 - voltage) * 24) / 160;
} else if (voltage < 3000) {
percentage = 100 - ((3000 - voltage) * 58) / 100;
} else if (voltage >= 3000) {
percentage = 100;
}
return percentage;
}
//
// Appends the attribute value to Write or to Report
// Adds to buf:
// - n bytes: value (typically between 1 and 4 bytes, or bigger for strings)
// returns number of bytes of attribute, or <0 if error
int32_t encodeSingleAttribute(class SBuffer &buf, double val_d, const char *val_str, uint8_t attrtype) {
uint32_t len = Z_getDatatypeLen(attrtype); // pre-compute lenght, overloaded for variable length attributes
uint32_t u32 = val_d;
int32_t i32 = val_d;
float f32 = val_d;
switch (attrtype) {
// unsigned 8
case Zbool: // bool
case Zuint8: // uint8
case Zenum8: // enum8
case Zdata8: // data8
case Zmap8: // map8
buf.add8(u32);
break;
// unsigned 16
case Zuint16: // uint16
case Zenum16: // enum16
case Zdata16: // data16
case Zmap16: // map16
buf.add16(u32);
break;
// unisgned 32
case Zuint32: // uint32
case Zdata32: // data32
case Zmap32: // map32
case ZUTC: // UTC - epoch 32 bits, seconds since 1-Jan-2000
buf.add32(u32);
break;
// signed 8
case Zint8: // int8
buf.add8(i32);
break;
case Zint16: // int16
buf.add16(i32);
break;
case Zint32: // int32
buf.add32(i32);
break;
case Zsingle: // float
uint32_t *f_ptr;
buf.add32( *((uint32_t*)&f32) ); // cast float as uint32_t
break;
case Zstring:
case Zstring16:
{
if (nullptr == val_str) { return -2; }
size_t val_len = strlen(val_str);
if (val_len > 32) { val_len = 32; }
len = val_len + 1;
buf.add8(val_len);
if (Zstring16 == attrtype) {
buf.add8(0); // len is on 2 bytes
len++;
}
for (uint32_t i = 0; i < val_len; i++) {
buf.add8(val_str[i]);
}
}
break;
default:
return -1;
}
return len;
}
//
// parse a single attribute
//
// Input:
// json: json Object where to add the attribute
// attrid_str: the key for the attribute
// buf: the buffer to read from
// offset: location in the buffer to read from
// attrtype: type of attribute (byte) or -1 to read from the stream as first byte
// Output:
// return: the length in bytes of the attribute
uint32_t parseSingleAttribute(JsonObject& json, char *attrid_str, class SBuffer &buf,
uint32_t offset, int32_t attrtype = -1) {
uint32_t i = offset;
if (attrtype < 0) {
attrtype = buf.get8(i++);
}
// fallback - enter a null value
json[attrid_str] = (char*) nullptr;
uint32_t len = Z_getDatatypeLen(attrtype); // pre-compute lenght, overloaded for variable length attributes
// now parse accordingly to attr type
switch (attrtype) {
// case Znodata: // nodata
// case Zunk: // unk
// break;
case Zbool: // bool
case Zuint8: // uint8
case Zenum8: // enum8
{
uint8_t uint8_val = buf.get8(i);
// i += 1;
if (0xFF != uint8_val) {
json[attrid_str] = uint8_val;
}
}
break;
case Zuint16: // uint16
case Zenum16: // enum16
{
uint16_t uint16_val = buf.get16(i);
// i += 2;
if (0xFFFF != uint16_val) {
json[attrid_str] = uint16_val;
}
}
break;
case Zuint32: // uint32
case ZUTC: // UTC
{
uint32_t uint32_val = buf.get32(i);
// i += 4;
if (0xFFFFFFFF != uint32_val) {
json[attrid_str] = uint32_val;
}
}
break;
// Note: uint40, uint48, uint56, uint64 are displayed as Hex
// Note: int40, int48, int56, int64 are displayed as Hex
case Zuint40: // uint40
case Zuint48: // uint48
case Zuint56: // uint56
case Zuint64: // uint64
case Zint40: // int40
case Zint48: // int48
case Zint56: // int56
case Zint64: // int64
{
// uint8_t len = attrtype - 0x27; // 5 - 8
// print as HEX
char hex[2*len+1];
ToHex_P(buf.buf(i), len, hex, sizeof(hex));
json[attrid_str] = hex;
// i += len;
}
break;
case Zint8: // int8
{
int8_t int8_val = buf.get8(i);
// i += 1;
if (0x80 != int8_val) {
json[attrid_str] = int8_val;
}
}
break;
case Zint16: // int16
{
int16_t int16_val = buf.get16(i);
// i += 2;
if (0x8000 != int16_val) {
json[attrid_str] = int16_val;
}
}
break;
case Zint32: // int32
{
int32_t int32_val = buf.get32(i);
// i += 4;
if (0x80000000 != int32_val) {
json[attrid_str] = int32_val;
}
}
break;
case Zoctstr: // octet string, 1 byte len
case Zstring: // char string, 1 byte len
case Zoctstr16: // octet string, 2 bytes len
case Zstring16: // char string, 2 bytes len
// For strings, default is to try to do a real string, but reverts to octet stream if null char is present or on some exceptions
{
bool parse_as_string = true;
len = (attrtype <= 0x42) ? buf.get8(i) : buf.get16(i); // len is 8 or 16 bits
i += (attrtype <= 0x42) ? 1 : 2; // increment pointer
if (i + len > buf.len()) { // make sure we don't get past the buffer
len = buf.len() - i;
}
// check if we can safely use a string
if ((0x41 == attrtype) || (0x43 == attrtype)) { parse_as_string = false; }
if (parse_as_string) {
char str[len+1];
strncpy(str, buf.charptr(i), len);
str[len] = 0x00;
json[attrid_str] = str;
} else {
// print as HEX
char hex[2*len+1];
ToHex_P(buf.buf(i), len, hex, sizeof(hex));
json[attrid_str] = hex;
}
// i += len;
// break;
}
// i += buf.get8(i) + 1;
break;
case Zdata8: // data8
case Zmap8: // map8
{
uint8_t uint8_val = buf.get8(i);
// i += 1;
json[attrid_str] = uint8_val;
}
break;
case Zdata16: // data16
case Zmap16: // map16
{
uint16_t uint16_val = buf.get16(i);
// i += 2;
json[attrid_str] = uint16_val;
}
break;
case Zdata32: // data32
case Zmap32: // map32
{
uint32_t uint32_val = buf.get32(i);
// i += 4;
json[attrid_str] = uint32_val;
}
break;
case Zsingle: // float
{
uint32_t uint32_val = buf.get32(i);
float * float_val = (float*) &uint32_val;
// i += 4;
json[attrid_str] = *float_val;
}
break;
// TODO
case ZToD: // ToD
case Zdate: // date
case ZclusterId: // clusterId
case ZattribId: // attribId
case ZbacOID: // bacOID
case ZEUI64: // EUI64
case Zkey128: // key128
case Zsemi: // semi (float on 2 bytes)
break;
// Other un-implemented data types
case Zdata24: // data24
case Zdata40: // data40
case Zdata48: // data48
case Zdata56: // data56
case Zdata64: // data64
break;
// map<x>
case Zmap24: // map24
case Zmap40: // map40
case Zmap48: // map48
case Zmap56: // map56
case Zmap64: // map64
break;
case Zdouble: // double precision
{
uint64_t uint64_val = buf.get64(i);
double * double_val = (double*) &uint64_val;
// i += 8;
json[attrid_str] = *double_val;
}
break;
}
i += len;
// String pp; // pretty print
// json[attrid_str].prettyPrintTo(pp);
// // now store the attribute
// AddLog_P2(LOG_LEVEL_INFO, PSTR(D_LOG_ZIGBEE "ZCL attribute decoded, id %s, type 0x%02X, val=%s"),
// attrid_str, attrtype, pp.c_str());
return i - offset; // how much have we increased the index
}
// Generate an attribute name based on cluster number, attribute, and suffix if duplicates
void ZCLFrame::generateAttributeName(const JsonObject& json, uint16_t cluster, uint16_t attr, char *key, size_t key_len) {
uint32_t suffix = 1;
snprintf_P(key, key_len, PSTR("%04X/%04X"), cluster, attr);
while (json.containsKey(key)) {
suffix++;
snprintf_P(key, key_len, PSTR("%04X/%04X+%d"), cluster, attr, suffix); // add "0008/0001+2" suffix if duplicate
}
}
// First pass, parse all attributes in their native format
void ZCLFrame::parseReportAttributes(JsonObject& json, uint8_t offset) {
uint32_t i = offset;
uint32_t len = _payload.len();
while (len >= i + 3) {
uint16_t attrid = _payload.get16(i);
i += 2;
char key[16];
generateAttributeName(json, _cluster_id, attrid, key, sizeof(key));
// exception for Xiaomi lumi.weather - specific field to be treated as octet and not char
if ((0x0000 == _cluster_id) && (0xFF01 == attrid)) {
if (0x42 == _payload.get8(i)) {
_payload.set8(i, 0x41); // change type from 0x42 to 0x41
}
}
i += parseSingleAttribute(json, key, _payload, i);
}
}
// ZCL_READ_ATTRIBUTES
// TODO
void ZCLFrame::parseReadAttributes(JsonObject& json, uint8_t offset) {
uint32_t i = offset;
uint32_t len = _payload.len();
json[F(D_CMND_ZIGBEE_CLUSTER)] = _cluster_id;
JsonArray &attr_list = json.createNestedArray(F("Read"));
JsonObject &attr_names = json.createNestedObject(F("ReadNames"));
while (len >= 2 + i) {
uint16_t attrid = _payload.get16(i);
attr_list.add(attrid);
// find the attribute name
for (uint32_t i = 0; i < ARRAY_SIZE(Z_PostProcess); i++) {
const Z_AttributeConverter *converter = &Z_PostProcess[i];
uint16_t conv_cluster = CxToCluster(pgm_read_byte(&converter->cluster_short));
uint16_t conv_attribute = pgm_read_word(&converter->attribute);
if ((conv_cluster == _cluster_id) && (conv_attribute == attrid)) {
attr_names[(const __FlashStringHelper*) (Z_strings + pgm_read_word(&converter->name_offset))] = true;
break;
}
}
i += 2;
}
}
// ZCL_CONFIGURE_REPORTING_RESPONSE
void ZCLFrame::parseConfigAttributes(JsonObject& json, uint8_t offset) {
uint32_t i = offset;
uint32_t len = _payload.len();
JsonObject &config_rsp = json.createNestedObject(F("ConfigResponse"));
uint8_t status = _payload.get8(i);
config_rsp[F("Status")] = status;
config_rsp[F("StatusMsg")] = getZigbeeStatusMessage(status);
}
// ZCL_READ_REPORTING_CONFIGURATION_RESPONSE
void ZCLFrame::parseReadConfigAttributes(JsonObject& json, uint8_t offset) {
uint32_t i = offset;
uint32_t len = _payload.len();
// json[F(D_CMND_ZIGBEE_CLUSTER)] = _cluster_id; // TODO is it necessary?
JsonObject &attr_names = json.createNestedObject(F("ReadConfig"));
while (len >= i + 4) {
uint8_t status = _payload.get8(i);
uint8_t direction = _payload.get8(i+1);
uint16_t attrid = _payload.get16(i+2);
char attr_hex[12];
snprintf_P(attr_hex, sizeof(attr_hex), "%04X/%04X", _cluster_id, attrid);
JsonObject &attr_details = attr_names.createNestedObject(attr_hex);
if (direction) {
attr_details[F("DirectionReceived")] = true;
}
// find the attribute name
for (uint32_t i = 0; i < ARRAY_SIZE(Z_PostProcess); i++) {
const Z_AttributeConverter *converter = &Z_PostProcess[i];
uint16_t conv_cluster = CxToCluster(pgm_read_byte(&converter->cluster_short));
uint16_t conv_attribute = pgm_read_word(&converter->attribute);
if ((conv_cluster == _cluster_id) && (conv_attribute == attrid)) {
attr_details[(const __FlashStringHelper*) (Z_strings + pgm_read_word(&converter->name_offset))] = true;
break;
}
}
i += 4;
if (0 != status) {
attr_details[F("Status")] = status;
attr_details[F("StatusMsg")] = getZigbeeStatusMessage(status);
} else {
// no error, decode data
if (direction) {
// only Timeout period is present
uint16_t attr_timeout = _payload.get16(i);
i += 2;
attr_details[F("TimeoutPeriod")] = (0xFFFF == attr_timeout) ? -1 : attr_timeout;
} else {
// direction == 0, we have a data type
uint8_t attr_type = _payload.get8(i);
bool attr_discrete = Z_isDiscreteDataType(attr_type);
uint16_t attr_min_interval = _payload.get16(i+1);
uint16_t attr_max_interval = _payload.get16(i+3);
i += 5;
attr_details[F("MinInterval")] = (0xFFFF == attr_min_interval) ? -1 : attr_min_interval;
attr_details[F("MaxInterval")] = (0xFFFF == attr_max_interval) ? -1 : attr_max_interval;
if (!attr_discrete) {
// decode Reportable Change
char attr_name[20];
strcpy_P(attr_name, PSTR("ReportableChange"));
i += parseSingleAttribute(attr_details, attr_name, _payload, i, attr_type);
}
}
}
}
}
// ZCL_READ_ATTRIBUTES_RESPONSE
void ZCLFrame::parseReadAttributesResponse(JsonObject& json, uint8_t offset) {
uint32_t i = offset;
uint32_t len = _payload.len();
while (len >= i + 4) {
uint16_t attrid = _payload.get16(i);
i += 2;
uint8_t status = _payload.get8(i++);
if (0 == status) {
char key[16];
generateAttributeName(json, _cluster_id, attrid, key, sizeof(key));
i += parseSingleAttribute(json, key, _payload, i);
}
}
}
// ZCL_DEFAULT_RESPONSE
void ZCLFrame::parseResponse(void) {
if (_payload.len() < 2) { return; } // wrong format
uint8_t cmd = _payload.get8(0);
uint8_t status = _payload.get8(1);
DynamicJsonBuffer jsonBuffer;
JsonObject& json = jsonBuffer.createObject();
// "Device"
char s[12];
snprintf_P(s, sizeof(s), PSTR("0x%04X"), _srcaddr);
json[F(D_JSON_ZIGBEE_DEVICE)] = s;
// "Name"
const char * friendlyName = zigbee_devices.getFriendlyName(_srcaddr);
if (friendlyName) {
json[F(D_JSON_ZIGBEE_NAME)] = (char*) friendlyName;
}
// "Command"
snprintf_P(s, sizeof(s), PSTR("%04X!%02X"), _cluster_id, cmd);
json[F(D_JSON_ZIGBEE_CMD)] = s;
// "Status"
json[F(D_JSON_ZIGBEE_STATUS)] = status;
// "StatusMessage"
json[F(D_JSON_ZIGBEE_STATUS_MSG)] = getZigbeeStatusMessage(status);
// Add Endpoint
json[F(D_CMND_ZIGBEE_ENDPOINT)] = _srcendpoint;
// Add Group if non-zero
if (_groupaddr) {
json[F(D_CMND_ZIGBEE_GROUP)] = _groupaddr;
}
// Add linkquality
json[F(D_CMND_ZIGBEE_LINKQUALITY)] = _linkquality;
String msg("");
msg.reserve(100);
json.printTo(msg);
Response_P(PSTR("{\"" D_JSON_ZIGBEE_RESPONSE "\":%s}"), msg.c_str());
MqttPublishPrefixTopicRulesProcess_P(RESULT_OR_TELE, PSTR(D_JSON_ZIGBEEZCL_RECEIVED));
}
// Parse non-normalized attributes
void ZCLFrame::parseClusterSpecificCommand(JsonObject& json, uint8_t offset) {
convertClusterSpecific(json, _cluster_id, _cmd_id, _frame_control.b.direction, _srcaddr, _srcendpoint, _payload);
#ifndef USE_ZIGBEE_NO_READ_ATTRIBUTES // read attributes unless disabled
sendHueUpdate(_srcaddr, _groupaddr, _cluster_id, _cmd_id, _frame_control.b.direction);
#endif
}
// ======================================================================
// Record Manuf
int32_t Z_ManufKeepFunc(const class ZCLFrame *zcl, uint16_t shortaddr, JsonObject& json, const char *name, JsonVariant& value, const String &new_name, uint16_t cluster, uint16_t attr) {
zigbee_devices.setManufId(shortaddr, value.as<const char*>());
return 1;
}
// Record ModelId
int32_t Z_ModelKeepFunc(const class ZCLFrame *zcl, uint16_t shortaddr, JsonObject& json, const char *name, JsonVariant& value, const String &new_name, uint16_t cluster, uint16_t attr) {
zigbee_devices.setModelId(shortaddr, value.as<const char*>());
return 1;
}
// Record BatteryPercentage
int32_t Z_BatteryPercentageKeepFunc(const class ZCLFrame *zcl, uint16_t shortaddr, JsonObject& json, const char *name, JsonVariant& value, const String &new_name, uint16_t cluster, uint16_t attr) {
zigbee_devices.setBatteryPercent(shortaddr, json[new_name]);
return 1;
}
// Add pressure unit
int32_t Z_AddPressureUnitFunc(const class ZCLFrame *zcl, uint16_t shortaddr, JsonObject& json, const char *name, JsonVariant& value, const String &new_name, uint16_t cluster, uint16_t attr) {
json[new_name] = F(D_UNIT_PRESSURE);
return 0; // keep original key
}
// Publish a message for `"Occupancy":0` when the timer expired
int32_t Z_OccupancyCallback(uint16_t shortaddr, uint16_t groupaddr, uint16_t cluster, uint8_t endpoint, uint32_t value) {
DynamicJsonBuffer jsonBuffer;
JsonObject& json = jsonBuffer.createObject();
json[F(OCCUPANCY)] = 0;
zigbee_devices.jsonPublishNow(shortaddr, json);
return 0; // Fix GCC 10.1 warning
}
// Aqara Cube
int32_t Z_AqaraCubeFunc(const class ZCLFrame *zcl, uint16_t shortaddr, JsonObject& json, const char *name, JsonVariant& value, const String &new_name, uint16_t cluster, uint16_t attr) {
const char * modelId_c = zigbee_devices.getModelId(shortaddr); // null if unknown
String modelId((char*) modelId_c);
if (modelId.startsWith(F("lumi.sensor_cube"))) { // only for Aqara cube
int32_t val = value;
const __FlashStringHelper *aqara_cube = F("AqaraCube");
const __FlashStringHelper *aqara_cube_side = F("AqaraCubeSide");
const __FlashStringHelper *aqara_cube_from_side = F("AqaraCubeFromSide");
switch (val) {
case 0:
json[aqara_cube] = F("shake");
break;
case 2:
json[aqara_cube] = F("wakeup");
break;
case 3:
json[aqara_cube] = F("fall");
break;
case 64 ... 127:
json[aqara_cube] = F("flip90");
json[aqara_cube_side] = val % 8;
json[aqara_cube_from_side] = (val - 64) / 8;
break;
case 128 ... 132:
json[aqara_cube] = F("flip180");
json[aqara_cube_side] = val - 128;
break;
case 256 ... 261:
json[aqara_cube] = F("slide");
json[aqara_cube_side] = val - 256;
break;
case 512 ... 517:
json[aqara_cube] = F("tap");
json[aqara_cube_side] = val - 512;
break;
}
return 1;
}
// Source: https://github.com/kirovilya/ioBroker.zigbee
// +---+
// | 2 |
// +---+---+---+
// | 4 | 0 | 1 |
// +---+---+---+
// |M5I|
// +---+
// | 3 |
// +---+
// Side 5 is with the MI logo, side 3 contains the battery door.
// presentValue = 0 = shake
// presentValue = 2 = wakeup
// presentValue = 3 = fly/fall
// presentValue = y + x * 8 + 64 = 90º Flip from side x on top to side y on top
// presentValue = x + 128 = 180º flip to side x on top
// presentValue = x + 256 = push/slide cube while side x is on top
// presentValue = x + 512 = double tap while side x is on top
return 0;
}
// Aqara Vibration Sensor - special proprietary attributes
int32_t Z_AqaraVibrationFunc(const class ZCLFrame *zcl, uint16_t shortaddr, JsonObject& json, const char *name, JsonVariant& value, const String &new_name, uint16_t cluster, uint16_t attr) {
//json[new_name] = value;
switch (attr) {
case 0x0055:
{
int32_t ivalue = value;
const __FlashStringHelper * svalue;
switch (ivalue) {
case 1: svalue = F("vibrate"); break;
case 2: svalue = F("tilt"); break;
case 3: svalue = F("drop"); break;
default: svalue = F("unknown"); break;
}
json[new_name] = svalue;
}
break;
// case 0x0503:
// break;
// case 0x0505:
// break;
case 0x0508:
{
// see https://github.com/Koenkk/zigbee2mqtt/issues/295 and http://faire-ca-soi-meme.fr/domotique/2018/09/03/test-xiaomi-aqara-vibration-sensor/
// report accelerometer measures
String hex = value;
SBuffer buf2 = SBuffer::SBufferFromHex(hex.c_str(), hex.length());
int16_t x, y, z;
z = buf2.get16(0);
y = buf2.get16(2);
x = buf2.get16(4);
JsonArray& xyz = json.createNestedArray(new_name);
xyz.add(x);
xyz.add(y);
xyz.add(z);
// calculate angles
float X = x;
float Y = y;
float Z = z;
int32_t Angle_X = 0.5f + atanf(X/sqrtf(z*z+y*y)) * f_180pi;
int32_t Angle_Y = 0.5f + atanf(Y/sqrtf(x*x+z*z)) * f_180pi;
int32_t Angle_Z = 0.5f + atanf(Z/sqrtf(x*x+y*y)) * f_180pi;
JsonArray& angles = json.createNestedArray(F("AqaraAngles"));
angles.add(Angle_X);
angles.add(Angle_Y);
angles.add(Angle_Z);
}
break;
}
return 1; // remove original key
}
int32_t Z_AqaraSensorFunc(const class ZCLFrame *zcl, uint16_t shortaddr, JsonObject& json, const char *name, JsonVariant& value, const String &new_name, uint16_t cluster, uint16_t attr) {
String hex = value;
SBuffer buf2 = SBuffer::SBufferFromHex(hex.c_str(), hex.length());
uint32_t i = 0;
uint32_t len = buf2.len();
char tmp[] = "tmp"; // for obscure reasons, it must be converted from const char* to char*, otherwise ArduinoJson gets confused
JsonVariant sub_value;
const char * modelId_c = zigbee_devices.getModelId(shortaddr); // null if unknown
String modelId((char*) modelId_c);
while (len >= 2 + i) {
uint8_t attrid = buf2.get8(i++);
i += parseSingleAttribute(json, tmp, buf2, i);
float val = json[tmp];
json.remove(tmp);
bool translated = false; // were we able to translate to a known format?
if (0x01 == attrid) {
float batteryvoltage = val / 1000.0f;
json[F("BatteryVoltage")] = batteryvoltage;
uint8_t batterypercentage = toPercentageCR2032(val);
json[F("BatteryPercentage")] = batterypercentage;
zigbee_devices.setBatteryPercent(shortaddr, batterypercentage);
// deprecated
json[F(D_JSON_VOLTAGE)] = batteryvoltage;
json[F("Battery")] = toPercentageCR2032(val);
} else if ((nullptr != modelId) && (0 == zcl->getManufCode())) {
translated = true;
if (modelId.startsWith(F("lumi.sensor_ht")) ||
modelId.startsWith(F("lumi.weather"))) { // Temp sensor
// Filter according to prefix of model name
// onla Aqara Temp/Humidity has manuf_code of zero. If non-zero we skip the parameters
if (0x64 == attrid) {
json[F(D_JSON_TEMPERATURE)] = val / 100.0f;
} else if (0x65 == attrid) {
json[F(D_JSON_HUMIDITY)] = val / 100.0f;
} else if (0x66 == attrid) {
json[F(D_JSON_PRESSURE)] = val / 100.0f;
json[F(D_JSON_PRESSURE_UNIT)] = F(D_UNIT_PRESSURE); // hPa
}
} else if (modelId.startsWith(F("lumi.sensor_smoke"))) { // gas leak
if (0x64 == attrid) {
json[F("SmokeDensity")] = val;
}
} else if (modelId.startsWith(F("lumi.sensor_natgas"))) { // gas leak
if (0x64 == attrid) {
json[F("GasDensity")] = val;
}
} else {
translated = false; // we didn't find a match
}
// } else if (0x115F == zcl->getManufCode()) { // Aqara Motion Sensor, still unknown field
}
if (!translated) {
if (attrid >= 100) { // payload is always above 0x64 or 100
char attr_name[12];
snprintf_P(attr_name, sizeof(attr_name), PSTR("Xiaomi_%02X"), attrid);
json[attr_name] = val;
}
}
}
return 1; // remove original key
}
// ======================================================================
// apply the transformation from the converter
int32_t Z_ApplyConverter(const class ZCLFrame *zcl, uint16_t shortaddr, JsonObject& json, const char *name, JsonVariant& value, const String &new_name,
uint16_t cluster, uint16_t attr, int8_t multiplier, uint8_t cb) {
// apply multiplier if needed
if (1 == multiplier) { // copy unchanged
json[new_name] = value;
} else if (0 != multiplier) {
if (multiplier > 0) {
json[new_name] = ((float)value) * multiplier;
} else {
json[new_name] = ((float)value) / (-multiplier);
}
}
// apply callback if needed
Z_AttrConverter func = nullptr;
switch (cb) {
case Z_Nop:
return 1; // drop original key
case Z_AddPressureUnit:
func = &Z_AddPressureUnitFunc;
break;
case Z_ManufKeep:
func = &Z_ManufKeepFunc;
break;
case Z_ModelKeep:
func = &Z_ModelKeepFunc;
break;
case Z_AqaraSensor:
func = &Z_AqaraSensorFunc;
break;
case Z_AqaraVibration:
func = &Z_AqaraVibrationFunc;
break;
case Z_AqaraCube:
func = &Z_AqaraCubeFunc;
break;
case Z_BatteryPercentage:
func = &Z_BatteryPercentageKeepFunc;
break;
};
if (func) {
return (*func)(zcl, shortaddr, json, name, value, new_name, cluster, attr);
}
return 1; // Fix GCC 10.1 warning
}
void ZCLFrame::postProcessAttributes(uint16_t shortaddr, JsonObject& json) {
// source endpoint
uint8_t src_ep = _srcendpoint;
// iterate on json elements
for (auto kv : json) {
String key_string = kv.key;
const char * key = key_string.c_str();
JsonVariant& value = kv.value;
// Check that format looks like "CCCC/AAAA" or "CCCC/AAAA+d"
char * delimiter = strchr(key, '/');
char * delimiter2 = strchr(key, '+');
if (delimiter) {
uint16_t attribute;
uint16_t suffix = 1;
uint16_t cluster = strtoul(key, &delimiter, 16);
if (!delimiter2) {
attribute = strtoul(delimiter+1, nullptr, 16);
} else {
attribute = strtoul(delimiter+1, &delimiter2, 16);
suffix = strtoul(delimiter2+1, nullptr, 10);
}
// see if we need to update the Hue bulb status
if ((cluster == 0x0006) && ((attribute == 0x0000) || (attribute == 0x8000))) {
bool power = value;
zigbee_devices.updateHueState(shortaddr, &power, nullptr, nullptr, nullptr,
nullptr, nullptr, nullptr, nullptr, nullptr);
} else if ((cluster == 0x0008) && (attribute == 0x0000)) {
uint8_t dimmer = value;
zigbee_devices.updateHueState(shortaddr, nullptr, nullptr, &dimmer, nullptr,
nullptr, nullptr, nullptr, nullptr, nullptr);
} else if ((cluster == 0x0300) && (attribute == 0x0000)) {
uint16_t hue8 = value;
uint16_t hue = changeUIntScale(hue8, 0, 254, 0, 360); // change range from 0..254 to 0..360
zigbee_devices.updateHueState(shortaddr, nullptr, nullptr, nullptr, nullptr,
nullptr, &hue, nullptr, nullptr, nullptr);
} else if ((cluster == 0x0300) && (attribute == 0x0001)) {
uint8_t sat = value;
zigbee_devices.updateHueState(shortaddr, nullptr, nullptr, nullptr, &sat,
nullptr, nullptr, nullptr, nullptr, nullptr);
} else if ((cluster == 0x0300) && (attribute == 0x0003)) {
uint16_t x = value;
zigbee_devices.updateHueState(shortaddr, nullptr, nullptr, nullptr, nullptr,
nullptr, nullptr, &x, nullptr, nullptr);
} else if ((cluster == 0x0300) && (attribute == 0x0004)) {
uint16_t y = value;
zigbee_devices.updateHueState(shortaddr, nullptr, nullptr, nullptr, nullptr,
nullptr, nullptr, nullptr, &y, nullptr), nullptr;
} else if ((cluster == 0x0300) && (attribute == 0x0007)) {
uint16_t ct = value;
zigbee_devices.updateHueState(shortaddr, nullptr, nullptr, nullptr, nullptr,
&ct, nullptr, nullptr, nullptr, nullptr);
} else if ((cluster == 0x0300) && (attribute == 0x0008)) {
uint8_t colormode = value;
zigbee_devices.updateHueState(shortaddr, nullptr, &colormode, nullptr, nullptr,
nullptr, nullptr, nullptr, nullptr, nullptr);
}
// Iterate on filter
for (uint32_t i = 0; i < ARRAY_SIZE(Z_PostProcess); i++) {
const Z_AttributeConverter *converter = &Z_PostProcess[i];
uint16_t conv_cluster = CxToCluster(pgm_read_byte(&converter->cluster_short));
uint16_t conv_attribute = pgm_read_word(&converter->attribute);
int8_t conv_multiplier = pgm_read_byte(&converter->multiplier);
uint8_t conv_cb = pgm_read_byte(&converter->cb); // callback id
if ((conv_cluster == cluster) &&
((conv_attribute == attribute) || (conv_attribute == 0xFFFF)) ) {
String new_name_str = (const __FlashStringHelper*) (Z_strings + pgm_read_word(&converter->name_offset));
if (suffix > 1) { new_name_str += suffix; } // append suffix number
// else if (Settings.flag4.zb_index_ep) {
// if (zigbee_devices.countEndpoints(shortaddr) > 0) {
// new_name_str += _srcendpoint;
// }
// }
// apply the transformation
int32_t drop = Z_ApplyConverter(this, shortaddr, json, key, value, new_name_str, conv_cluster, conv_attribute, conv_multiplier, conv_cb);
if (drop) {
json.remove(key);
}
}
}
}
}
}
#endif // USE_ZIGBEE