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/*
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xdrv_23_zigbee_converters . ino - zigbee support for Tasmota
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Copyright ( C ) 2021 Theo Arends and Stephan Hadinger
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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
\ * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
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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 ,
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Zunk = 0xFF ,
// adding fake type for Tuya specific encodings
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Ztuya0 = Zoctstr ,
Ztuya1 = Zbool ,
Ztuya2 = Zint32 ,
Ztuya3 = Zstring ,
Ztuya4 = Zuint8 ,
Ztuya5 = Zuint32
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} ;
//
// 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 ;
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}
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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 ;
}
}
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// 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 ;
}
}
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typedef struct Z_AttributeConverter {
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uint8_t type ;
uint8_t cluster_short ;
uint16_t attribute ;
uint16_t name_offset ;
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uint8_t multiplier_idx ; // multiplier index for numerical value, use CmToMultiplier(), (if > 0 multiply by x, if <0 device by x)
// the high 4 bits are used to encode flags
// currently: 0x80 = this parameter needs to be exported to ZbData
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uint8_t mapping ; // high 4 bits = type, low 4 bits = offset in bytes from header
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// still room for a byte
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} Z_AttributeConverter ;
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// Get offset in bytes of attributes, starting after the header (skipping first 4 bytes)
# define Z_OFFSET(c,a) (offsetof(class c, a) - sizeof(Z_Data))
# define Z_CLASS(c) c // necessary to get a valid token without concatenation (which wouldn't work)
# define Z_MAPPING(c,a) (((((uint8_t)Z_CLASS(c)::type) & 0x0F) << 4) | Z_OFFSET(c,a))
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// lines with this marker, will be used to export automatically data to `ZbData`
// at the condition Z_MAPPING() is also used
const uint8_t Z_EXPORT_DATA = 0x80 ;
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// 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 ,
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Cx0101 , Cx0102 , Cx0201 , Cx0300 , Cx0400 , Cx0401 , Cx0402 , Cx0403 ,
Cx0404 , Cx0405 , Cx0406 , Cx0500 , Cx0702 , Cx0B01 , Cx0B04 , Cx0B05 ,
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CxEF00 , CxFCC0 , CxFCCC ,
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} ;
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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 ,
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0x0101 , 0x0102 , 0x0201 , 0x0300 , 0x0400 , 0x0401 , 0x0402 , 0x0403 ,
0x0404 , 0x0405 , 0x0406 , 0x0500 , 0x0702 , 0x0B01 , 0x0B04 , 0x0B05 ,
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0xEF00 , 0xFCC0 , 0xFCCC ,
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} ;
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uint16_t CxToCluster ( uint8_t cx ) {
if ( cx < ARRAY_SIZE ( Cx_cluster ) ) {
return pgm_read_word ( & Cx_cluster [ cx ] ) ;
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}
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return 0xFFFF ;
}
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uint8_t ClusterToCx ( uint16_t cluster ) {
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for ( uint32_t i = 0 ; i < ARRAY_SIZE ( Cx_cluster ) ; i + + ) {
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if ( pgm_read_word ( & Cx_cluster [ i ] ) = = cluster ) {
return i ;
}
}
return 0xFF ;
}
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// Multiplier contains only a limited set of values, so instead of storing the value
// we store an index in a table, and reduce it to 4 bits
enum Cm_multiplier_nibble {
Cm0 = 0 , Cm1 = 1 , Cm2 , Cm5 , Cm10 , Cm100 ,
// negative numbers
Cm_2 , Cm_5 , Cm_10 , Cm_100
} ;
const int8_t Cm_multiplier [ ] PROGMEM = {
0 , 1 , 2 , 5 , 10 , 100 ,
- 2 , - 5 , - 10 , - 100 ,
} ;
int8_t CmToMultiplier ( uint8_t cm ) {
cm = cm & 0x0F ; // get only low nibble
if ( cm < ARRAY_SIZE ( Cm_multiplier ) ) {
return pgm_read_byte ( & Cm_multiplier [ cm ] ) ;
}
return 1 ;
}
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// list of post-processing directives
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# pragma GCC diagnostic push
# pragma GCC diagnostic ignored "-Winvalid-offsetof" // avoid warnings since we're using offsetof() in a risky way
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const Z_AttributeConverter Z_PostProcess [ ] PROGMEM = {
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{ Zuint8 , Cx0000 , 0x0000 , Z_ ( ZCLVersion ) , Cm1 , 0 } ,
{ Zuint8 , Cx0000 , 0x0001 , Z_ ( AppVersion ) , Cm1 , 0 } ,
{ Zuint8 , Cx0000 , 0x0002 , Z_ ( StackVersion ) , Cm1 , 0 } ,
{ Zuint8 , Cx0000 , 0x0003 , Z_ ( HWVersion ) , Cm1 , 0 } ,
{ Zstring , Cx0000 , 0x0004 , Z_ ( Manufacturer ) , Cm1 , 0 } , // record Manufacturer
{ Zstring , Cx0000 , 0x0005 , Z_ ( ModelId ) , Cm1 , 0 } , // record Model
// { Zstring, Cx0000, 0x0004, Z_(Manufacturer), Cm1, Z_ManufKeep, 0 }, // record Manufacturer
// { Zstring, Cx0000, 0x0005, Z_(ModelId), Cm1, Z_ModelKeep, 0 }, // record Model
{ Zstring , Cx0000 , 0x0006 , Z_ ( DateCode ) , Cm1 , 0 } ,
{ Zenum8 , Cx0000 , 0x0007 , Z_ ( PowerSource ) , Cm1 , 0 } ,
{ Zenum8 , Cx0000 , 0x0008 , Z_ ( GenericDeviceClass ) , Cm1 , 0 } ,
{ Zenum8 , Cx0000 , 0x0009 , Z_ ( GenericDeviceType ) , Cm1 , 0 } ,
{ Zoctstr , Cx0000 , 0x000A , Z_ ( ProductCode ) , Cm1 , 0 } ,
{ Zstring , Cx0000 , 0x000B , Z_ ( ProductURL ) , Cm1 , 0 } ,
{ Zstring , Cx0000 , 0x4000 , Z_ ( SWBuildID ) , Cm1 , 0 } ,
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{ Zuint8 , Cx0000 , 0x4005 , Z_ ( MullerLightMode ) , Cm1 , 0 } ,
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// { Zunk, Cx0000, 0xFFFF, nullptr, Cm0, 0 }, // Remove all other values
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// Cmd 0x0A - Cluster 0x0000, attribute 0xFF01 - proprietary
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{ Zmap8 , Cx0000 , 0xFF01 , Z_ ( ) , Cm0 , 0 } ,
{ Zmap8 , Cx0000 , 0xFF02 , Z_ ( ) , Cm0 , 0 } ,
// { Zmap8, Cx0000, 0xFF01, Z_(), Cm0, Z_AqaraSensor, 0 },
// { Zmap8, Cx0000, 0xFF02, Z_(), Cm0, Z_AqaraSensor2, 0 },
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// Power Configuration cluster
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{ Zuint16 , Cx0001 , 0x0000 , Z_ ( MainsVoltage ) , Cm1 , 0 } ,
{ Zuint8 , Cx0001 , 0x0001 , Z_ ( MainsFrequency ) , Cm1 , 0 } ,
{ Zuint8 , Cx0001 , 0x0020 , Z_ ( BatteryVoltage ) , Cm_10 , 0 } , // divide by 10
{ Zuint8 , Cx0001 , 0x0021 , Z_ ( BatteryPercentage ) , Cm_2 , 0 } , // divide by 2
// { Zuint8, Cx0001, 0x0021, Z_(BatteryPercentage), Cm_2, Z_BatteryPercentage, 0 }, // divide by 2
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// Device Temperature Configuration cluster
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{ Zint16 , Cx0002 , 0x0000 , Z_ ( CurrentTemperature ) , Cm1 , 0 } ,
{ Zint16 , Cx0002 , 0x0001 , Z_ ( MinTempExperienced ) , Cm1 , 0 } ,
{ Zint16 , Cx0002 , 0x0002 , Z_ ( MaxTempExperienced ) , Cm1 , 0 } ,
{ Zuint16 , Cx0002 , 0x0003 , Z_ ( OverTempTotalDwell ) , Cm1 , 0 } ,
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// Identify cluster
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{ Zuint16 , Cx0003 , 0x0000 , Z_ ( IdentifyTime ) , Cm1 , 0 } ,
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// Groups cluster
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{ Zmap8 , Cx0004 , 0x0000 , Z_ ( GroupNameSupport ) , Cm1 , 0 } ,
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// Scenes cluster
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{ Zuint8 , Cx0005 , 0x0000 , Z_ ( SceneCount ) , Cm1 , 0 } ,
{ Zuint8 , Cx0005 , 0x0001 , Z_ ( CurrentScene ) , Cm1 , 0 } ,
{ Zuint16 , Cx0005 , 0x0002 , Z_ ( CurrentGroup ) , Cm1 , 0 } ,
{ Zbool , Cx0005 , 0x0003 , Z_ ( SceneValid ) , Cm1 , 0 } ,
//{ Zmap8, Cx0005, 0x0004, (NameSupport), Cm1, 0 },
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// On/off cluster
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{ Zbool , Cx0006 , 0x0000 , Z_ ( Power ) , Cm1 + Z_EXPORT_DATA , Z_MAPPING ( Z_Data_OnOff , power ) } ,
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{ Zenum8 , Cx0006 , 0x4003 , Z_ ( StartUpOnOff ) , Cm1 , 0 } ,
{ Zbool , Cx0006 , 0x8000 , Z_ ( Power ) , Cm1 , 0 } , // See 7280
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// On/Off Switch Configuration cluster
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{ Zenum8 , Cx0007 , 0x0000 , Z_ ( SwitchType ) , Cm1 , 0 } ,
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// Level Control cluster
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{ Zuint8 , Cx0008 , 0x0000 , Z_ ( Dimmer ) , Cm1 + Z_EXPORT_DATA , Z_MAPPING ( Z_Data_Light , dimmer ) } ,
{ Zmap8 , Cx0008 , 0x000F , Z_ ( DimmerOptions ) , Cm1 , 0 } ,
{ Zuint16 , Cx0008 , 0x0001 , Z_ ( DimmerRemainingTime ) , Cm1 , 0 } ,
{ Zuint16 , Cx0008 , 0x0010 , Z_ ( OnOffTransitionTime ) , Cm1 , 0 } ,
// { Zuint8, Cx0008, 0x0011, (OnLevel), Cm1, 0 },
// { Zuint16, Cx0008, 0x0012, (OnTransitionTime), Cm1, 0 },
// { Zuint16, Cx0008, 0x0013, (OffTransitionTime), Cm1, 0 },
// { Zuint16, Cx0008, 0x0014, (DefaultMoveRate), Cm1, 0 },
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// Alarms cluster
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{ Zuint16 , Cx0009 , 0x0000 , Z_ ( AlarmCount ) , Cm1 , 0 } ,
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// Time cluster
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{ ZUTC , Cx000A , 0x0000 , Z_ ( Time ) , Cm1 , 0 } ,
{ Zmap8 , Cx000A , 0x0001 , Z_ ( TimeStatus ) , Cm1 , 0 } ,
{ Zint32 , Cx000A , 0x0002 , Z_ ( TimeZone ) , Cm1 , 0 } ,
{ Zuint32 , Cx000A , 0x0003 , Z_ ( DstStart ) , Cm1 , 0 } ,
{ Zuint32 , Cx000A , 0x0004 , Z_ ( DstEnd ) , Cm1 , 0 } ,
{ Zint32 , Cx000A , 0x0005 , Z_ ( DstShift ) , Cm1 , 0 } ,
{ Zuint32 , Cx000A , 0x0006 , Z_ ( StandardTime ) , Cm1 , 0 } ,
{ Zuint32 , Cx000A , 0x0007 , Z_ ( LocalTime ) , Cm1 , 0 } ,
{ ZUTC , Cx000A , 0x0008 , Z_ ( LastSetTime ) , Cm1 , 0 } ,
{ ZUTC , Cx000A , 0x0009 , Z_ ( ValidUntilTime ) , Cm1 , 0 } ,
{ ZUTC , Cx000A , 0xFF00 , Z_ ( TimeEpoch ) , Cm1 , 0 } , // Tasmota specific, epoch
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// RSSI Location cluster
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{ Zdata8 , Cx000B , 0x0000 , Z_ ( LocationType ) , Cm1 , 0 } ,
{ Zenum8 , Cx000B , 0x0001 , Z_ ( LocationMethod ) , Cm1 , 0 } ,
{ Zuint16 , Cx000B , 0x0002 , Z_ ( LocationAge ) , Cm1 , 0 } ,
{ Zuint8 , Cx000B , 0x0003 , Z_ ( QualityMeasure ) , Cm1 , 0 } ,
{ Zuint8 , Cx000B , 0x0004 , Z_ ( NumberOfDevices ) , Cm1 , 0 } ,
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// Analog Input cluster
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// { 0xFF, Cx000C, 0x0004, (AnalogInActiveText), Cm1, 0 },
{ Zstring , Cx000C , 0x001C , Z_ ( AnalogInDescription ) , Cm1 , 0 } ,
// { 0xFF, Cx000C, 0x002E, (AnalogInInactiveText), Cm1, 0 },
{ Zsingle , Cx000C , 0x0041 , Z_ ( AnalogInMaxValue ) , Cm1 , 0 } ,
{ Zsingle , Cx000C , 0x0045 , Z_ ( AnalogInMinValue ) , Cm1 , 0 } ,
{ Zbool , Cx000C , 0x0051 , Z_ ( AnalogInOutOfService ) , Cm1 , 0 } ,
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{ Zsingle , Cx000C , 0x0055 , Z_ ( AnalogValue ) , Cm1 , 0 } ,
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// { 0xFF, Cx000C, 0x0057, (AnalogInPriorityArray),Cm1, 0 },
{ Zenum8 , Cx000C , 0x0067 , Z_ ( AnalogInReliability ) , Cm1 , 0 } ,
// { 0xFF, Cx000C, 0x0068, (AnalogInRelinquishDefault),Cm1, 0 },
{ Zsingle , Cx000C , 0x006A , Z_ ( AnalogInResolution ) , Cm1 , 0 } ,
{ Zmap8 , Cx000C , 0x006F , Z_ ( AnalogInStatusFlags ) , Cm1 , 0 } ,
{ Zenum16 , Cx000C , 0x0075 , Z_ ( AnalogInEngineeringUnits ) , Cm1 , 0 } ,
{ Zuint32 , Cx000C , 0x0100 , Z_ ( AnalogInApplicationType ) , Cm1 , 0 } ,
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{ Zuint16 , Cx000C , 0xFF55 , Z_ ( AqaraRotate ) , Cm1 , 0 } ,
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{ Zuint16 , Cx000C , 0xFF05 , Z_ ( Aqara_FF05 ) , Cm1 , 0 } ,
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// Analog Output cluster
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{ Zstring , Cx000D , 0x001C , Z_ ( AnalogOutDescription ) , Cm1 , 0 } ,
{ Zsingle , Cx000D , 0x0041 , Z_ ( AnalogOutMaxValue ) , Cm1 , 0 } ,
{ Zsingle , Cx000D , 0x0045 , Z_ ( AnalogOutMinValue ) , Cm1 , 0 } ,
{ Zbool , Cx000D , 0x0051 , Z_ ( AnalogOutOutOfService ) , Cm1 , 0 } ,
{ Zsingle , Cx000D , 0x0055 , Z_ ( AnalogOutValue ) , Cm1 , 0 } ,
// { Zunk, Cx000D, 0x0057, (AnalogOutPriorityArray),Cm1, 0 },
{ Zenum8 , Cx000D , 0x0067 , Z_ ( AnalogOutReliability ) , Cm1 , 0 } ,
{ Zsingle , Cx000D , 0x0068 , Z_ ( AnalogOutRelinquishDefault ) , Cm1 , 0 } ,
{ Zsingle , Cx000D , 0x006A , Z_ ( AnalogOutResolution ) , Cm1 , 0 } ,
{ Zmap8 , Cx000D , 0x006F , Z_ ( AnalogOutStatusFlags ) , Cm1 , 0 } ,
{ Zenum16 , Cx000D , 0x0075 , Z_ ( AnalogOutEngineeringUnits ) , Cm1 , 0 } ,
{ Zuint32 , Cx000D , 0x0100 , Z_ ( AnalogOutApplicationType ) , Cm1 , 0 } ,
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// Analog Value cluster
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{ Zstring , Cx000E , 0x001C , Z_ ( AnalogDescription ) , Cm1 , 0 } ,
{ Zbool , Cx000E , 0x0051 , Z_ ( AnalogOutOfService ) , Cm1 , 0 } ,
{ Zsingle , Cx000E , 0x0055 , Z_ ( AnalogValue ) , Cm1 , 0 } ,
{ Zunk , Cx000E , 0x0057 , Z_ ( AnalogPriorityArray ) , Cm1 , 0 } ,
{ Zenum8 , Cx000E , 0x0067 , Z_ ( AnalogReliability ) , Cm1 , 0 } ,
{ Zsingle , Cx000E , 0x0068 , Z_ ( AnalogRelinquishDefault ) , Cm1 , 0 } ,
{ Zmap8 , Cx000E , 0x006F , Z_ ( AnalogStatusFlags ) , Cm1 , 0 } ,
{ Zenum16 , Cx000E , 0x0075 , Z_ ( AnalogEngineeringUnits ) , Cm1 , 0 } ,
{ Zuint32 , Cx000E , 0x0100 , Z_ ( AnalogApplicationType ) , Cm1 , 0 } ,
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// Binary Input cluster
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{ Zstring , Cx000F , 0x0004 , Z_ ( BinaryInActiveText ) , Cm1 , 0 } ,
{ Zstring , Cx000F , 0x001C , Z_ ( BinaryInDescription ) , Cm1 , 0 } ,
{ Zstring , Cx000F , 0x002E , Z_ ( BinaryInInactiveText ) , Cm1 , 0 } ,
{ Zbool , Cx000F , 0x0051 , Z_ ( BinaryInOutOfService ) , Cm1 , 0 } ,
{ Zenum8 , Cx000F , 0x0054 , Z_ ( BinaryInPolarity ) , Cm1 , 0 } ,
{ Zstring , Cx000F , 0x0055 , Z_ ( BinaryInValue ) , Cm1 , 0 } ,
// { 0xFF, Cx000F, 0x0057, (BinaryInPriorityArray),Cm1, 0 },
{ Zenum8 , Cx000F , 0x0067 , Z_ ( BinaryInReliability ) , Cm1 , 0 } ,
{ Zmap8 , Cx000F , 0x006F , Z_ ( BinaryInStatusFlags ) , Cm1 , 0 } ,
{ Zuint32 , Cx000F , 0x0100 , Z_ ( BinaryInApplicationType ) , Cm1 , 0 } ,
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// Binary Output cluster
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{ Zstring , Cx0010 , 0x0004 , Z_ ( BinaryOutActiveText ) , Cm1 , 0 } ,
{ Zstring , Cx0010 , 0x001C , Z_ ( BinaryOutDescription ) , Cm1 , 0 } ,
{ Zstring , Cx0010 , 0x002E , Z_ ( BinaryOutInactiveText ) , Cm1 , 0 } ,
{ Zuint32 , Cx0010 , 0x0042 , Z_ ( BinaryOutMinimumOffTime ) , Cm1 , 0 } ,
{ Zuint32 , Cx0010 , 0x0043 , Z_ ( BinaryOutMinimumOnTime ) , Cm1 , 0 } ,
{ Zbool , Cx0010 , 0x0051 , Z_ ( BinaryOutOutOfService ) , Cm1 , 0 } ,
{ Zenum8 , Cx0010 , 0x0054 , Z_ ( BinaryOutPolarity ) , Cm1 , 0 } ,
{ Zbool , Cx0010 , 0x0055 , Z_ ( BinaryOutValue ) , Cm1 , 0 } ,
// { Zunk, Cx0010, 0x0057, (BinaryOutPriorityArray),Cm1, 0 },
{ Zenum8 , Cx0010 , 0x0067 , Z_ ( BinaryOutReliability ) , Cm1 , 0 } ,
{ Zbool , Cx0010 , 0x0068 , Z_ ( BinaryOutRelinquishDefault ) , Cm1 , 0 } ,
{ Zmap8 , Cx0010 , 0x006F , Z_ ( BinaryOutStatusFlags ) , Cm1 , 0 } ,
{ Zuint32 , Cx0010 , 0x0100 , Z_ ( BinaryOutApplicationType ) , Cm1 , 0 } ,
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// Binary Value cluster
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{ Zstring , Cx0011 , 0x0004 , Z_ ( BinaryActiveText ) , Cm1 , 0 } ,
{ Zstring , Cx0011 , 0x001C , Z_ ( BinaryDescription ) , Cm1 , 0 } ,
{ Zstring , Cx0011 , 0x002E , Z_ ( BinaryInactiveText ) , Cm1 , 0 } ,
{ Zuint32 , Cx0011 , 0x0042 , Z_ ( BinaryMinimumOffTime ) , Cm1 , 0 } ,
{ Zuint32 , Cx0011 , 0x0043 , Z_ ( BinaryMinimumOnTime ) , Cm1 , 0 } ,
{ Zbool , Cx0011 , 0x0051 , Z_ ( BinaryOutOfService ) , Cm1 , 0 } ,
{ Zbool , Cx0011 , 0x0055 , Z_ ( BinaryValue ) , Cm1 , 0 } ,
// { Zunk, Cx0011, 0x0057, (BinaryPriorityArray), Cm1, 0 },
{ Zenum8 , Cx0011 , 0x0067 , Z_ ( BinaryReliability ) , Cm1 , 0 } ,
{ Zbool , Cx0011 , 0x0068 , Z_ ( BinaryRelinquishDefault ) , Cm1 , 0 } ,
{ Zmap8 , Cx0011 , 0x006F , Z_ ( BinaryStatusFlags ) , Cm1 , 0 } ,
{ Zuint32 , Cx0011 , 0x0100 , Z_ ( BinaryApplicationType ) , Cm1 , 0 } ,
2020-04-16 18:36:14 +01:00
2019-10-20 15:43:50 +01:00
// Multistate Input cluster
2020-10-09 18:10:36 +01:00
// { Zunk, Cx0012, 0x000E, (MultiInStateText), Cm1, 0 },
{ Zstring , Cx0012 , 0x001C , Z_ ( MultiInDescription ) , Cm1 , 0 } ,
{ Zuint16 , Cx0012 , 0x004A , Z_ ( MultiInNumberOfStates ) , Cm1 , 0 } ,
{ Zbool , Cx0012 , 0x0051 , Z_ ( MultiInOutOfService ) , Cm1 , 0 } ,
{ Zuint16 , Cx0012 , 0x0055 , Z_ ( MultiInValue ) , Cm1 , 0 } ,
// { Zuint16, Cx0012, 0x0055, Z_(MultiInValue), Cm0, Z_AqaraCube, 0 },
// { Zuint16, Cx0012, 0x0055, Z_(MultiInValue), Cm0, Z_AqaraButton, 0 },
{ Zenum8 , Cx0012 , 0x0067 , Z_ ( MultiInReliability ) , Cm1 , 0 } ,
{ Zmap8 , Cx0012 , 0x006F , Z_ ( MultiInStatusFlags ) , Cm1 , 0 } ,
{ Zuint32 , Cx0012 , 0x0100 , Z_ ( MultiInApplicationType ) , Cm1 , 0 } ,
2020-04-16 18:36:14 +01:00
2020-05-29 21:52:45 +01:00
// Multistate output
2020-10-09 18:10:36 +01:00
// { Zunk, Cx0013, 0x000E, (MultiOutStateText), Cm1, 0 },
{ Zstring , Cx0013 , 0x001C , Z_ ( MultiOutDescription ) , Cm1 , 0 } ,
{ Zuint16 , Cx0013 , 0x004A , Z_ ( MultiOutNumberOfStates ) , Cm1 , 0 } ,
{ Zbool , Cx0013 , 0x0051 , Z_ ( MultiOutOutOfService ) , Cm1 , 0 } ,
{ Zuint16 , Cx0013 , 0x0055 , Z_ ( MultiOutValue ) , Cm1 , 0 } ,
// { Zunk, Cx0013, 0x0057, (MultiOutPriorityArray),Cm1, 0 },
{ Zenum8 , Cx0013 , 0x0067 , Z_ ( MultiOutReliability ) , Cm1 , 0 } ,
{ Zuint16 , Cx0013 , 0x0068 , Z_ ( MultiOutRelinquishDefault ) , Cm1 , 0 } ,
{ Zmap8 , Cx0013 , 0x006F , Z_ ( MultiOutStatusFlags ) , Cm1 , 0 } ,
{ Zuint32 , Cx0013 , 0x0100 , Z_ ( MultiOutApplicationType ) , Cm1 , 0 } ,
2020-05-29 21:52:45 +01:00
// Multistate Value cluster
2020-10-09 18:10:36 +01:00
// { Zunk, Cx0014, 0x000E, (MultiStateText), Cm1, 0 },
{ Zstring , Cx0014 , 0x001C , Z_ ( MultiDescription ) , Cm1 , 0 } ,
{ Zuint16 , Cx0014 , 0x004A , Z_ ( MultiNumberOfStates ) , Cm1 , 0 } ,
{ Zbool , Cx0014 , 0x0051 , Z_ ( MultiOutOfService ) , Cm1 , 0 } ,
{ Zuint16 , Cx0014 , 0x0055 , Z_ ( MultiValue ) , Cm1 , 0 } ,
{ Zenum8 , Cx0014 , 0x0067 , Z_ ( MultiReliability ) , Cm1 , 0 } ,
{ Zuint16 , Cx0014 , 0x0068 , Z_ ( MultiRelinquishDefault ) , Cm1 , 0 } ,
{ Zmap8 , Cx0014 , 0x006F , Z_ ( MultiStatusFlags ) , Cm1 , 0 } ,
{ Zuint32 , Cx0014 , 0x0100 , Z_ ( MultiApplicationType ) , Cm1 , 0 } ,
2020-05-29 21:52:45 +01:00
// Power Profile cluster
2020-10-09 18:10:36 +01:00
{ Zuint8 , Cx001A , 0x0000 , Z_ ( TotalProfileNum ) , Cm1 , 0 } ,
{ Zbool , Cx001A , 0x0001 , Z_ ( MultipleScheduling ) , Cm1 , 0 } ,
{ Zmap8 , Cx001A , 0x0002 , Z_ ( EnergyFormatting ) , Cm1 , 0 } ,
{ Zbool , Cx001A , 0x0003 , Z_ ( EnergyRemote ) , Cm1 , 0 } ,
{ Zmap8 , Cx001A , 0x0004 , Z_ ( ScheduleMode ) , Cm1 , 0 } ,
2020-05-29 21:52:45 +01:00
// Poll Control cluster
2020-10-09 18:10:36 +01:00
{ Zuint32 , Cx0020 , 0x0000 , Z_ ( CheckinInterval ) , Cm1 , 0 } ,
{ Zuint32 , Cx0020 , 0x0001 , Z_ ( LongPollInterval ) , Cm1 , 0 } ,
{ Zuint16 , Cx0020 , 0x0002 , Z_ ( ShortPollInterval ) , Cm1 , 0 } ,
{ Zuint16 , Cx0020 , 0x0003 , Z_ ( FastPollTimeout ) , Cm1 , 0 } ,
{ Zuint32 , Cx0020 , 0x0004 , Z_ ( CheckinIntervalMin ) , Cm1 , 0 } ,
{ Zuint32 , Cx0020 , 0x0005 , Z_ ( LongPollIntervalMin ) , Cm1 , 0 } ,
{ Zuint16 , Cx0020 , 0x0006 , Z_ ( FastPollTimeoutMax ) , Cm1 , 0 } ,
2020-05-29 21:52:45 +01:00
// Shade Configuration cluster
2020-10-09 18:10:36 +01:00
{ Zuint16 , Cx0100 , 0x0000 , Z_ ( PhysicalClosedLimit ) , Cm1 , 0 } ,
{ Zuint8 , Cx0100 , 0x0001 , Z_ ( MotorStepSize ) , Cm1 , 0 } ,
{ Zmap8 , Cx0100 , 0x0002 , Z_ ( Status ) , Cm1 , 0 } ,
{ Zuint16 , Cx0100 , 0x0010 , Z_ ( ClosedLimit ) , Cm1 , 0 } ,
{ Zenum8 , Cx0100 , 0x0011 , Z_ ( Mode ) , Cm1 , 0 } ,
2020-05-29 21:52:45 +01:00
// Door Lock cluster
2020-10-09 18:10:36 +01:00
{ Zenum8 , Cx0101 , 0x0000 , Z_ ( LockState ) , Cm1 , 0 } ,
{ Zenum8 , Cx0101 , 0x0001 , Z_ ( LockType ) , Cm1 , 0 } ,
{ Zbool , Cx0101 , 0x0002 , Z_ ( ActuatorEnabled ) , Cm1 , 0 } ,
{ Zenum8 , Cx0101 , 0x0003 , Z_ ( DoorState ) , Cm1 , 0 } ,
{ Zuint32 , Cx0101 , 0x0004 , Z_ ( DoorOpenEvents ) , Cm1 , 0 } ,
{ Zuint32 , Cx0101 , 0x0005 , Z_ ( DoorClosedEvents ) , Cm1 , 0 } ,
{ Zuint16 , Cx0101 , 0x0006 , Z_ ( OpenPeriod ) , Cm1 , 0 } ,
2020-05-29 21:52:45 +01:00
// Aqara Lumi Vibration Sensor
2020-10-09 18:10:36 +01:00
{ Zuint16 , Cx0101 , 0x0055 , Z_ ( AqaraVibrationMode ) , Cm1 , 0 } ,
{ Zuint16 , Cx0101 , 0x0503 , Z_ ( AqaraVibrationsOrAngle ) , Cm1 , 0 } ,
{ Zuint32 , Cx0101 , 0x0505 , Z_ ( AqaraVibration505 ) , Cm1 , 0 } ,
{ Zuint48 , Cx0101 , 0x0508 , Z_ ( AqaraAccelerometer ) , Cm1 , 0 } ,
2020-05-29 21:52:45 +01:00
// Window Covering cluster
2020-10-09 18:10:36 +01:00
{ Zenum8 , Cx0102 , 0x0000 , Z_ ( WindowCoveringType ) , Cm1 , 0 } ,
{ Zuint16 , Cx0102 , 0x0001 , Z_ ( PhysicalClosedLimitLift ) , Cm1 , 0 } ,
{ Zuint16 , Cx0102 , 0x0002 , Z_ ( PhysicalClosedLimitTilt ) , Cm1 , 0 } ,
{ Zuint16 , Cx0102 , 0x0003 , Z_ ( CurrentPositionLift ) , Cm1 , 0 } ,
{ Zuint16 , Cx0102 , 0x0004 , Z_ ( CurrentPositionTilt ) , Cm1 , 0 } ,
{ Zuint16 , Cx0102 , 0x0005 , Z_ ( NumberofActuationsLift ) , Cm1 , 0 } ,
{ Zuint16 , Cx0102 , 0x0006 , Z_ ( NumberofActuationsTilt ) , Cm1 , 0 } ,
{ Zmap8 , Cx0102 , 0x0007 , Z_ ( ConfigStatus ) , Cm1 , 0 } ,
{ Zuint8 , Cx0102 , 0x0008 , Z_ ( CurrentPositionLiftPercentage ) , Cm1 , 0 } ,
{ Zuint8 , Cx0102 , 0x0009 , Z_ ( CurrentPositionTiltPercentage ) , Cm1 , 0 } ,
{ Zuint16 , Cx0102 , 0x0010 , Z_ ( InstalledOpenLimitLift ) , Cm1 , 0 } ,
{ Zuint16 , Cx0102 , 0x0011 , Z_ ( InstalledClosedLimitLift ) , Cm1 , 0 } ,
{ Zuint16 , Cx0102 , 0x0012 , Z_ ( InstalledOpenLimitTilt ) , Cm1 , 0 } ,
{ Zuint16 , Cx0102 , 0x0013 , Z_ ( InstalledClosedLimitTilt ) , Cm1 , 0 } ,
{ Zuint16 , Cx0102 , 0x0014 , Z_ ( VelocityLift ) , Cm1 , 0 } ,
{ Zuint16 , Cx0102 , 0x0015 , Z_ ( AccelerationTimeLift ) , Cm1 , 0 } ,
{ Zuint16 , Cx0102 , 0x0016 , Z_ ( DecelerationTimeLift ) , Cm1 , 0 } ,
{ Zmap8 , Cx0102 , 0x0017 , Z_ ( Mode ) , Cm1 , 0 } ,
{ Zoctstr , Cx0102 , 0x0018 , Z_ ( IntermediateSetpointsLift ) , Cm1 , 0 } ,
{ Zoctstr , Cx0102 , 0x0019 , Z_ ( IntermediateSetpointsTilt ) , Cm1 , 0 } ,
2020-05-29 21:52:45 +01:00
2020-09-27 14:26:06 +01:00
// Thermostat
2020-10-09 18:10:36 +01:00
{ Zint16 , Cx0201 , 0x0000 , Z_ ( LocalTemperature ) , Cm_100 , Z_MAPPING ( Z_Data_Thermo , temperature ) } ,
{ Zint16 , Cx0201 , 0x0001 , Z_ ( OutdoorTemperature ) , Cm_100 , 0 } ,
{ Zuint8 , Cx0201 , 0x0007 , Z_ ( PICoolingDemand ) , Cm1 , Z_MAPPING ( Z_Data_Thermo , th_setpoint ) } ,
{ Zuint8 , Cx0201 , 0x0008 , Z_ ( PIHeatingDemand ) , Cm1 , Z_MAPPING ( Z_Data_Thermo , th_setpoint ) } ,
{ Zint8 , Cx0201 , 0x0010 , Z_ ( LocalTemperatureCalibration ) , Cm_10 , 0 } ,
{ Zint16 , Cx0201 , 0x0011 , Z_ ( OccupiedCoolingSetpoint ) , Cm_100 , Z_MAPPING ( Z_Data_Thermo , temperature_target ) } ,
{ Zint16 , Cx0201 , 0x0012 , Z_ ( OccupiedHeatingSetpoint ) , Cm_100 , Z_MAPPING ( Z_Data_Thermo , temperature_target ) } ,
{ Zint16 , Cx0201 , 0x0013 , Z_ ( UnoccupiedCoolingSetpoint ) , Cm_100 , 0 } ,
{ Zint16 , Cx0201 , 0x0014 , Z_ ( UnoccupiedHeatingSetpoint ) , Cm_100 , 0 } ,
{ Zmap8 , Cx0201 , 0x001A , Z_ ( RemoteSensing ) , Cm1 , 0 } ,
{ Zenum8 , Cx0201 , 0x001B , Z_ ( ControlSequenceOfOperation ) , Cm1 , 0 } ,
{ Zenum8 , Cx0201 , 0x001C , Z_ ( SystemMode ) , Cm1 , 0 } ,
2020-09-27 14:26:06 +01:00
// below is Eurotronic specific
2020-10-09 18:10:36 +01:00
{ Zenum8 , Cx0201 , 0x4000 , Z_ ( TRVMode ) , Cm1 , 0 } ,
2020-10-11 18:41:23 +01:00
{ Zuint8 , Cx0201 , 0x4001 , Z_ ( ValvePosition ) , Cm1 , 0 } ,
2020-10-09 18:10:36 +01:00
{ Zuint8 , Cx0201 , 0x4002 , Z_ ( EurotronicErrors ) , Cm1 , 0 } ,
{ Zint16 , Cx0201 , 0x4003 , Z_ ( CurrentTemperatureSetPoint ) , Cm_100 , 0 } ,
2020-12-15 18:57:50 +00:00
{ Zuint24 , Cx0201 , 0x4008 , Z_ ( EurotronicHostFlags ) , Cm1 , 0 } ,
// below are synthetic virtual attributes used to decode EurotronicHostFlags
// Last byte acts as a field mask for the lowest byte value
{ Zbool , Cx0201 , 0xF002 , Z_ ( TRVMirrorDisplay ) , Cm1 , 0 } ,
{ Zbool , Cx0201 , 0xF004 , Z_ ( TRVBoost ) , Cm1 , 0 } ,
{ Zbool , Cx0201 , 0xF010 , Z_ ( TRVWindowOpen ) , Cm1 , 0 } ,
{ Zbool , Cx0201 , 0xF080 , Z_ ( TRVChildProtection ) , Cm1 , 0 } ,
2020-10-09 18:10:36 +01:00
// below are virtual attributes to simplify ZbData import/export
{ Zuint8 , Cx0201 , 0xFFF0 , Z_ ( ThSetpoint ) , Cm1 + Z_EXPORT_DATA , Z_MAPPING ( Z_Data_Thermo , th_setpoint ) } ,
{ Zint16 , Cx0201 , 0xFFF1 , Z_ ( TempTarget ) , Cm_100 + Z_EXPORT_DATA , Z_MAPPING ( Z_Data_Thermo , temperature_target ) } ,
2020-09-27 14:26:06 +01:00
2020-05-29 21:52:45 +01:00
// Color Control cluster
2020-10-09 18:10:36 +01:00
{ Zuint8 , Cx0300 , 0x0000 , Z_ ( Hue ) , Cm1 + Z_EXPORT_DATA , Z_MAPPING ( Z_Data_Light , hue ) } ,
{ Zuint8 , Cx0300 , 0x0001 , Z_ ( Sat ) , Cm1 + Z_EXPORT_DATA , Z_MAPPING ( Z_Data_Light , sat ) } ,
{ Zuint16 , Cx0300 , 0x0002 , Z_ ( RemainingTime ) , Cm1 , 0 } ,
{ Zuint16 , Cx0300 , 0x0003 , Z_ ( X ) , Cm1 + Z_EXPORT_DATA , Z_MAPPING ( Z_Data_Light , x ) } ,
{ Zuint16 , Cx0300 , 0x0004 , Z_ ( Y ) , Cm1 + Z_EXPORT_DATA , Z_MAPPING ( Z_Data_Light , y ) } ,
{ Zenum8 , Cx0300 , 0x0005 , Z_ ( DriftCompensation ) , Cm1 , 0 } ,
{ Zstring , Cx0300 , 0x0006 , Z_ ( CompensationText ) , Cm1 , 0 } ,
{ Zuint16 , Cx0300 , 0x0007 , Z_ ( CT ) , Cm1 + Z_EXPORT_DATA , Z_MAPPING ( Z_Data_Light , ct ) } ,
{ Zenum8 , Cx0300 , 0x0008 , Z_ ( ColorMode ) , Cm1 + Z_EXPORT_DATA , Z_MAPPING ( Z_Data_Light , colormode ) } ,
{ Zuint8 , Cx0300 , 0x0010 , Z_ ( NumberOfPrimaries ) , Cm1 , 0 } ,
{ Zuint16 , Cx0300 , 0x0011 , Z_ ( Primary1X ) , Cm1 , 0 } ,
{ Zuint16 , Cx0300 , 0x0012 , Z_ ( Primary1Y ) , Cm1 , 0 } ,
{ Zuint8 , Cx0300 , 0x0013 , Z_ ( Primary1Intensity ) , Cm1 , 0 } ,
{ Zuint16 , Cx0300 , 0x0015 , Z_ ( Primary2X ) , Cm1 , 0 } ,
{ Zuint16 , Cx0300 , 0x0016 , Z_ ( Primary2Y ) , Cm1 , 0 } ,
{ Zuint8 , Cx0300 , 0x0017 , Z_ ( Primary2Intensity ) , Cm1 , 0 } ,
{ Zuint16 , Cx0300 , 0x0019 , Z_ ( Primary3X ) , Cm1 , 0 } ,
{ Zuint16 , Cx0300 , 0x001A , Z_ ( Primary3Y ) , Cm1 , 0 } ,
{ Zuint8 , Cx0300 , 0x001B , Z_ ( Primary3Intensity ) , Cm1 , 0 } ,
{ Zuint16 , Cx0300 , 0x0030 , Z_ ( WhitePointX ) , Cm1 , 0 } ,
{ Zuint16 , Cx0300 , 0x0031 , Z_ ( WhitePointY ) , Cm1 , 0 } ,
{ Zuint16 , Cx0300 , 0x0032 , Z_ ( ColorPointRX ) , Cm1 , 0 } ,
{ Zuint16 , Cx0300 , 0x0033 , Z_ ( ColorPointRY ) , Cm1 , 0 } ,
{ Zuint8 , Cx0300 , 0x0034 , Z_ ( ColorPointRIntensity ) , Cm1 , 0 } ,
{ Zuint16 , Cx0300 , 0x0036 , Z_ ( ColorPointGX ) , Cm1 , 0 } ,
{ Zuint16 , Cx0300 , 0x0037 , Z_ ( ColorPointGY ) , Cm1 , 0 } ,
{ Zuint8 , Cx0300 , 0x0038 , Z_ ( ColorPointGIntensity ) , Cm1 , 0 } ,
{ Zuint16 , Cx0300 , 0x003A , Z_ ( ColorPointBX ) , Cm1 , 0 } ,
{ Zuint16 , Cx0300 , 0x003B , Z_ ( ColorPointBY ) , Cm1 , 0 } ,
{ Zuint8 , Cx0300 , 0x003C , Z_ ( ColorPointBIntensity ) , Cm1 , 0 } ,
2020-05-29 21:52:45 +01:00
// Illuminance Measurement cluster
2020-10-28 19:59:55 +00:00
{ Zuint16 , Cx0400 , 0x0000 , Z_ ( Illuminance ) , Cm1 + Z_EXPORT_DATA , Z_MAPPING ( Z_Data_PIR , illuminance ) } , // Illuminance (in Lux)
2020-10-09 18:10:36 +01:00
{ Zuint16 , Cx0400 , 0x0001 , Z_ ( IlluminanceMinMeasuredValue ) , Cm1 , 0 } , //
{ Zuint16 , Cx0400 , 0x0002 , Z_ ( IlluminanceMaxMeasuredValue ) , Cm1 , 0 } , //
{ Zuint16 , Cx0400 , 0x0003 , Z_ ( IlluminanceTolerance ) , Cm1 , 0 } , //
{ Zenum8 , Cx0400 , 0x0004 , Z_ ( IlluminanceLightSensorType ) , Cm1 , 0 } , //
{ Zunk , Cx0400 , 0xFFFF , Z_ ( ) , Cm0 , 0 } , // Remove all other values
2020-05-29 21:52:45 +01:00
// Illuminance Level Sensing cluster
2020-10-09 18:10:36 +01:00
{ Zenum8 , Cx0401 , 0x0000 , Z_ ( IlluminanceLevelStatus ) , Cm1 , 0 } , // Illuminance (in Lux)
{ Zenum8 , Cx0401 , 0x0001 , Z_ ( IlluminanceLightSensorType ) , Cm1 , 0 } , // LightSensorType
{ Zuint16 , Cx0401 , 0x0010 , Z_ ( IlluminanceTargetLevel ) , Cm1 , 0 } , //
{ Zunk , Cx0401 , 0xFFFF , Z_ ( ) , Cm0 , 0 } , // Remove all other values
2020-05-29 21:52:45 +01:00
// Temperature Measurement cluster
2020-10-09 18:10:36 +01:00
{ Zint16 , Cx0402 , 0x0000 , Z_ ( Temperature ) , Cm_100 + Z_EXPORT_DATA , Z_MAPPING ( Z_Data_Thermo , temperature ) } ,
{ Zint16 , Cx0402 , 0x0001 , Z_ ( TemperatureMinMeasuredValue ) , Cm_100 , 0 } , //
{ Zint16 , Cx0402 , 0x0002 , Z_ ( TemperatureMaxMeasuredValue ) , Cm_100 , 0 } , //
{ Zuint16 , Cx0402 , 0x0003 , Z_ ( TemperatureTolerance ) , Cm_100 , 0 } , //
{ Zunk , Cx0402 , 0xFFFF , Z_ ( ) , Cm0 , 0 } , // Remove all other values
2020-05-29 21:52:45 +01:00
// Pressure Measurement cluster
2020-10-09 18:10:36 +01:00
{ Zint16 , Cx0403 , 0x0000 , Z_ ( Pressure ) , Cm1 + Z_EXPORT_DATA , Z_MAPPING ( Z_Data_Thermo , pressure ) } , // Pressure
{ Zint16 , Cx0403 , 0x0001 , Z_ ( PressureMinMeasuredValue ) , Cm1 , 0 } , //
{ Zint16 , Cx0403 , 0x0002 , Z_ ( PressureMaxMeasuredValue ) , Cm1 , 0 } , //
{ Zuint16 , Cx0403 , 0x0003 , Z_ ( PressureTolerance ) , Cm1 , 0 } , //
{ Zint16 , Cx0403 , 0x0010 , Z_ ( PressureScaledValue ) , Cm1 , 0 } , //
{ Zint16 , Cx0403 , 0x0011 , Z_ ( PressureMinScaledValue ) , Cm1 , 0 } , //
{ Zint16 , Cx0403 , 0x0012 , Z_ ( PressureMaxScaledValue ) , Cm1 , 0 } , //
{ Zuint16 , Cx0403 , 0x0013 , Z_ ( PressureScaledTolerance ) , Cm1 , 0 } , //
{ Zint8 , Cx0403 , 0x0014 , Z_ ( PressureScale ) , Cm1 , 0 } , //
{ Zint16 , Cx0403 , 0xFFF0 , Z_ ( SeaPressure ) , Cm1 , Z_MAPPING ( Z_Data_Thermo , pressure ) } , // Pressure at Sea Level, Tasmota specific
{ Zunk , Cx0403 , 0xFFFF , Z_ ( ) , Cm0 , 0 } , // Remove all other Pressure values
2020-05-29 21:52:45 +01:00
// Flow Measurement cluster
2020-10-09 18:10:36 +01:00
{ Zuint16 , Cx0404 , 0x0000 , Z_ ( FlowRate ) , Cm_10 , 0 } , // Flow (in m3/h)
{ Zuint16 , Cx0404 , 0x0001 , Z_ ( FlowMinMeasuredValue ) , Cm1 , 0 } , //
{ Zuint16 , Cx0404 , 0x0002 , Z_ ( FlowMaxMeasuredValue ) , Cm1 , 0 } , //
{ Zuint16 , Cx0404 , 0x0003 , Z_ ( FlowTolerance ) , Cm1 , 0 } , //
{ Zunk , Cx0404 , 0xFFFF , Z_ ( ) , Cm0 , 0 } , // Remove all other values
2020-05-29 21:52:45 +01:00
// Relative Humidity Measurement cluster
2020-10-09 18:10:36 +01:00
{ Zuint16 , Cx0405 , 0x0000 , Z_ ( Humidity ) , Cm_100 + Z_EXPORT_DATA , Z_MAPPING ( Z_Data_Thermo , humidity ) } , // Humidity
{ Zuint16 , Cx0405 , 0x0001 , Z_ ( HumidityMinMeasuredValue ) , Cm1 , 0 } , //
{ Zuint16 , Cx0405 , 0x0002 , Z_ ( HumidityMaxMeasuredValue ) , Cm1 , 0 } , //
{ Zuint16 , Cx0405 , 0x0003 , Z_ ( HumidityTolerance ) , Cm1 , 0 } , //
{ Zunk , Cx0405 , 0xFFFF , Z_ ( ) , Cm0 , 0 } , // Remove all other values
2020-05-29 21:52:45 +01:00
// Occupancy Sensing cluster
2020-10-28 19:59:55 +00:00
{ Zmap8 , Cx0406 , 0x0000 , Z_ ( Occupancy ) , Cm1 + Z_EXPORT_DATA , Z_MAPPING ( Z_Data_PIR , occupancy ) } , // Occupancy (map8)
2020-10-09 18:10:36 +01:00
{ Zenum8 , Cx0406 , 0x0001 , Z_ ( OccupancySensorType ) , Cm1 , 0 } , // OccupancySensorType
{ Zunk , Cx0406 , 0xFFFF , Z_ ( ) , Cm0 , 0 } , // Remove all other values
2020-05-29 21:52:45 +01:00
2020-08-08 11:17:37 +01:00
// IAS Cluster (Intruder Alarm System)
2020-11-13 17:55:06 +00:00
{ Zenum8 , Cx0500 , 0x0000 , Z_ ( ZoneState ) , Cm1 , 0 } , // Occupancy (map8)
{ Zenum16 , Cx0500 , 0x0001 , Z_ ( ZoneType ) , Cm1 + Z_EXPORT_DATA , Z_MAPPING ( Z_Data_Alarm , zone_type ) } , // Zone type for sensor
{ Zmap16 , Cx0500 , 0x0002 , Z_ ( ZoneStatus ) , Cm1 + Z_EXPORT_DATA , Z_MAPPING ( Z_Data_Alarm , zone_status ) } , // Zone status for sensor
{ Zuint8 , Cx0500 , 0xFFF0 + ZA_CIE , Z_ ( CIE ) , Cm1 , 0 } ,
{ Zuint8 , Cx0500 , 0xFFF0 + ZA_PIR , Z_ ( Occupancy ) , Cm1 , 0 } , // normally converted to the actual Occupancy 0406/0000
{ Zuint8 , Cx0500 , 0xFFF0 + ZA_Contact , Z_ ( Contact ) , Cm1 , Z_MAPPING ( Z_Data_Alarm , zone_status ) } , // We fit the first bit in the LSB
{ Zuint8 , Cx0500 , 0xFFF0 + ZA_Fire , Z_ ( Fire ) , Cm1 , 0 } ,
{ Zuint8 , Cx0500 , 0xFFF0 + ZA_Water , Z_ ( Water ) , Cm1 , 0 } ,
{ Zuint8 , Cx0500 , 0xFFF0 + ZA_CO , Z_ ( CO ) , Cm1 , 0 } ,
{ Zuint8 , Cx0500 , 0xFFF0 + ZA_Personal , Z_ ( PersonalAlarm ) , Cm1 , 0 } ,
{ Zuint8 , Cx0500 , 0xFFF0 + ZA_Movement , Z_ ( Movement ) , Cm1 , 0 } ,
{ Zuint8 , Cx0500 , 0xFFF0 + ZA_Panic , Z_ ( Panic ) , Cm1 , 0 } ,
{ Zuint8 , Cx0500 , 0xFFF0 + ZA_GlassBreak , Z_ ( GlassBreak ) , Cm1 , 0 } ,
2020-08-08 11:17:37 +01:00
2020-08-28 21:53:34 +01:00
// Metering (Smart Energy) cluster
2020-11-22 16:38:04 +00:00
{ Zuint48 , Cx0702 , 0x0000 , Z_ ( EnergyTotal ) , Cm1 , 0 } ,
2020-08-28 21:53:34 +01:00
2020-05-29 21:52:45 +01:00
// Meter Identification cluster
2020-10-09 18:10:36 +01:00
{ Zstring , Cx0B01 , 0x0000 , Z_ ( CompanyName ) , Cm1 , 0 } ,
{ Zuint16 , Cx0B01 , 0x0001 , Z_ ( MeterTypeID ) , Cm1 , 0 } ,
{ Zuint16 , Cx0B01 , 0x0004 , Z_ ( DataQualityID ) , Cm1 , 0 } ,
{ Zstring , Cx0B01 , 0x0005 , Z_ ( CustomerName ) , Cm1 , 0 } ,
{ Zoctstr , Cx0B01 , 0x0006 , Z_ ( Model ) , Cm1 , 0 } ,
{ Zoctstr , Cx0B01 , 0x0007 , Z_ ( PartNumber ) , Cm1 , 0 } ,
{ Zoctstr , Cx0B01 , 0x0008 , Z_ ( ProductRevision ) , Cm1 , 0 } ,
{ Zoctstr , Cx0B01 , 0x000A , Z_ ( SoftwareRevision ) , Cm1 , 0 } ,
{ Zstring , Cx0B01 , 0x000B , Z_ ( UtilityName ) , Cm1 , 0 } ,
{ Zstring , Cx0B01 , 0x000C , Z_ ( POD ) , Cm1 , 0 } ,
{ Zint24 , Cx0B01 , 0x000D , Z_ ( AvailablePower ) , Cm1 , 0 } ,
{ Zint24 , Cx0B01 , 0x000E , Z_ ( PowerThreshold ) , Cm1 , 0 } ,
2020-05-29 21:52:45 +01:00
2020-08-28 21:53:34 +01:00
// Electrical Measurement cluster
2020-10-09 18:10:36 +01:00
{ Zuint16 , Cx0B04 , 0x0505 , Z_ ( RMSVoltage ) , Cm1 + Z_EXPORT_DATA , Z_MAPPING ( Z_Data_Plug , mains_voltage ) } ,
{ Zuint16 , Cx0B04 , 0x0508 , Z_ ( RMSCurrent ) , Cm1 , 0 } ,
{ Zint16 , Cx0B04 , 0x050B , Z_ ( ActivePower ) , Cm1 + Z_EXPORT_DATA , Z_MAPPING ( Z_Data_Plug , mains_power ) } ,
2020-11-22 16:38:04 +00:00
{ Zint16 , Cx0B04 , 0x050E , Z_ ( ReactivePower ) , Cm1 , 0 } ,
{ Zint16 , Cx0B04 , 0x050F , Z_ ( ApparentPower ) , Cm1 , 0 } ,
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// Diagnostics cluster
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{ Zuint16 , Cx0B05 , 0x0000 , Z_ ( NumberOfResets ) , Cm1 , 0 } ,
{ Zuint16 , Cx0B05 , 0x0001 , Z_ ( PersistentMemoryWrites ) , Cm1 , 0 } ,
{ Zuint8 , Cx0B05 , 0x011C , Z_ ( LastMessageLQI ) , Cm1 , 0 } ,
{ Zuint8 , Cx0B05 , 0x011D , Z_ ( LastMessageRSSI ) , Cm1 , 0 } ,
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2020-10-11 18:41:23 +01:00
// Tuya Moes specific - 0xEF00
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// Mapping of Tuya type with internal mapping
// 0x00 - Zoctstr (len N)
// 0x01 - Ztuya1 (len 1) - equivalent to Zuint8 without invalid value handling
// 0x02 - Ztuya4 (len 4) - equivalent to Zint32 in big endian and without invalid value handling
// 0x03 - Zstr (len N)
// 0x04 - Ztuya1 (len 1)
// 0x05 - Ztuya4u (len 1/2/4) - equivalent to Zuint32
{ Ztuya0 , CxEF00 , 0x0070 , Z_ ( TuyaScheduleWorkdays ) , Cm1 , 0 } ,
{ Ztuya0 , CxEF00 , 0x0071 , Z_ ( TuyaScheduleHolidays ) , Cm1 , 0 } ,
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{ Ztuya1 , CxEF00 , 0x0101 , Z_ ( Power ) , Cm1 , 0 } ,
{ Ztuya1 , CxEF00 , 0x0102 , Z_ ( Power2 ) , Cm1 , 0 } ,
{ Ztuya1 , CxEF00 , 0x0103 , Z_ ( Power3 ) , Cm1 , 0 } ,
{ Ztuya1 , CxEF00 , 0x0104 , Z_ ( Power4 ) , Cm1 , 0 } ,
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{ Ztuya1 , CxEF00 , 0x0107 , Z_ ( TuyaChildLock ) , Cm1 , 0 } ,
{ Ztuya1 , CxEF00 , 0x0112 , Z_ ( TuyaWindowDetection ) , Cm1 , 0 } ,
{ Ztuya1 , CxEF00 , 0x0114 , Z_ ( TuyaValveDetection ) , Cm1 , 0 } ,
{ Ztuya1 , CxEF00 , 0x0174 , Z_ ( TuyaAutoLock ) , Cm1 , 0 } ,
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{ Zint16 , CxEF00 , 0x0202 , Z_ ( TuyaTempTarget ) , Cm_10 , Z_MAPPING ( Z_Data_Thermo , temperature_target ) } ,
{ Zint16 , CxEF00 , 0x0203 , Z_ ( LocalTemperature ) , Cm_10 , Z_MAPPING ( Z_Data_Thermo , temperature ) } , // will be overwritten by actual LocalTemperature
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{ Ztuya2 , CxEF00 , 0x0215 , Z_ ( TuyaBattery ) , Cm1 , 0 } , // TODO check equivalent?
{ Ztuya2 , CxEF00 , 0x0266 , Z_ ( TuyaMinTemp ) , Cm1 , 0 } ,
{ Ztuya2 , CxEF00 , 0x0267 , Z_ ( TuyaMaxTemp ) , Cm1 , 0 } ,
{ Ztuya2 , CxEF00 , 0x0269 , Z_ ( TuyaBoostTime ) , Cm1 , 0 } ,
{ Ztuya2 , CxEF00 , 0x026B , Z_ ( TuyaComfortTemp ) , Cm1 , 0 } ,
{ Ztuya2 , CxEF00 , 0x026C , Z_ ( TuyaEcoTemp ) , Cm1 , 0 } ,
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{ Zuint8 , CxEF00 , 0x026D , Z_ ( TuyaValvePosition ) , Cm1 , Z_MAPPING ( Z_Data_Thermo , th_setpoint ) } ,
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{ Ztuya2 , CxEF00 , 0x0272 , Z_ ( TuyaAwayTemp ) , Cm1 , 0 } ,
{ Ztuya2 , CxEF00 , 0x0275 , Z_ ( TuyaAwayDays ) , Cm1 , 0 } ,
{ Ztuya4 , CxEF00 , 0x0404 , Z_ ( TuyaPreset ) , Cm1 , 0 } ,
{ Ztuya4 , CxEF00 , 0x0405 , Z_ ( TuyaFanMode ) , Cm1 , 0 } ,
{ Ztuya4 , CxEF00 , 0x046A , Z_ ( TuyaForceMode ) , Cm1 , 0 } ,
{ Ztuya4 , CxEF00 , 0x046F , Z_ ( TuyaWeekSelect ) , Cm1 , 0 } ,
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// Aqara Opple spacific
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{ Zuint8 , CxFCC0 , 0x0009 , Z_ ( OppleMode ) , Cm1 , 0 } ,
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// Terncy specific - 0xFCCC
{ Zuint16 , CxFCCC , 0x001A , Z_ ( TerncyDuration ) , Cm1 , 0 } ,
{ Zint16 , CxFCCC , 0x001B , Z_ ( TerncyRotate ) , Cm1 , 0 } ,
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} ;
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# pragma GCC diagnostic pop
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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 ;
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// Find the attribute details by attribute name
// If not found:
// - returns nullptr
const __FlashStringHelper * zigbeeFindAttributeByName ( const char * command ,
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uint16_t * cluster , uint16_t * attribute , int8_t * multiplier ,
uint8_t * zigbee_type = nullptr , Z_Data_Type * data_type = nullptr , uint8_t * map_offset = nullptr ) {
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for ( uint32_t i = 0 ; i < ARRAY_SIZE ( Z_PostProcess ) ; i + + ) {
const Z_AttributeConverter * converter = & Z_PostProcess [ i ] ;
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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 ) ) ) {
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if ( cluster ) { * cluster = CxToCluster ( pgm_read_byte ( & converter - > cluster_short ) ) ; }
if ( attribute ) { * attribute = pgm_read_word ( & converter - > attribute ) ; }
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if ( multiplier ) { * multiplier = CmToMultiplier ( pgm_read_byte ( & converter - > multiplier_idx ) ) ; }
if ( zigbee_type ) { * zigbee_type = pgm_read_byte ( & converter - > type ) ; }
uint8_t conv_mapping = pgm_read_byte ( & converter - > mapping ) ;
if ( data_type ) { * data_type = ( Z_Data_Type ) ( ( conv_mapping & 0xF0 ) > > 4 ) ; }
if ( map_offset ) { * map_offset = ( conv_mapping & 0x0F ) ; }
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return ( const __FlashStringHelper * ) ( Z_strings + pgm_read_word ( & converter - > name_offset ) ) ;
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}
}
return nullptr ;
}
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//
// Find attribute details: Name, Type, Multiplier by cuslter/attr_id
//
const __FlashStringHelper * zigbeeFindAttributeById ( uint16_t cluster , uint16_t attr_id ,
uint8_t * attr_type , int8_t * multiplier ) {
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_attr_id = pgm_read_word ( & converter - > attribute ) ;
if ( ( conv_cluster = = cluster ) & & ( conv_attr_id = = attr_id ) ) {
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if ( multiplier ) { * multiplier = CmToMultiplier ( pgm_read_byte ( & converter - > multiplier_idx ) ) ; }
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if ( attr_type ) { * attr_type = pgm_read_byte ( & converter - > type ) ; }
return ( const __FlashStringHelper * ) ( Z_strings + pgm_read_word ( & converter - > name_offset ) ) ;
}
}
return nullptr ;
}
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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 ,
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uint8_t linkquality , uint8_t securityuse , uint8_t seqnumber ) :
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_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 ) ,
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_linkquality ( linkquality ) , _securityuse ( securityuse ) , _seqnumber ( seqnumber )
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{
_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 " \" :{ "
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" \" groupid \" :%d, " " \" clusterid \" : \" 0x%04X \" , " " \" srcaddr \" : \" 0x%04X \" , "
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" \" srcendpoint \" :%d, " " \" dstendpoint \" :%d, " " \" wasbroadcast \" :%d, "
" \" " D_CMND_ZIGBEE_LINKQUALITY " \" :%d, " " \" securityuse \" :%d, " " \" seqnumber \" :%d, "
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" \" fc \" : \" 0x%02X \" , "
" \" frametype \" :%d, \" direction \" :%d, \" disableresp \" :%d, "
" \" manuf \" : \" 0x%04X \" , \" transact \" :%d, "
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" \" cmdid \" : \" 0x%02X \" , \" payload \" : \" %s \" }} " ) ,
_groupaddr , _cluster_id , _srcaddr ,
_srcendpoint , _dstendpoint , _wasbroadcast ,
_linkquality , _securityuse , _seqnumber ,
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_frame_control ,
_frame_control . b . frame_type , _frame_control . b . direction , _frame_control . b . disable_def_resp ,
_manuf_code , _transact_seq , _cmd_id ,
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hex_char ) ;
if ( Settings . flag3 . tuya_serial_mqtt_publish ) {
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MqttPublishPrefixTopicRulesProcess_P ( TELE , PSTR ( D_RSLT_SENSOR ) ) ;
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} else {
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AddLogZ_P ( LOG_LEVEL_DEBUG , PSTR ( D_LOG_ZIGBEE " %s " ) , TasmotaGlobal . mqtt_data ) ;
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}
}
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 ,
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uint8_t linkquality , uint8_t securityuse , uint8_t seqnumber ) { // parse a raw frame and build the ZCL frame object
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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 ,
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linkquality , securityuse , seqnumber ) ;
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return zcl_frame ;
}
bool isClusterSpecificCommand ( void ) {
return _frame_control . b . frame_type & 1 ;
}
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void parseReportAttributes ( Z_attribute_list & attr_list ) ;
void generateSyntheticAttributes ( Z_attribute_list & attr_list ) ;
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void removeInvalidAttributes ( Z_attribute_list & attr_list ) ;
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void computeSyntheticAttributes ( Z_attribute_list & attr_list ) ;
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void generateCallBacks ( Z_attribute_list & attr_list ) ;
void parseReadAttributes ( Z_attribute_list & attr_list ) ;
void parseReadAttributesResponse ( Z_attribute_list & attr_list ) ;
void parseReadConfigAttributes ( Z_attribute_list & attr_list ) ;
void parseConfigAttributes ( Z_attribute_list & attr_list ) ;
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void parseWriteAttributesResponse ( Z_attribute_list & attr_list ) ;
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void parseResponse ( void ) ;
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void parseResponse_inner ( uint8_t cmd , bool cluster_specific , uint8_t status ) ;
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void parseClusterSpecificCommand ( Z_attribute_list & attr_list ) ;
// synthetic attributes converters
void syntheticAqaraSensor ( Z_attribute_list & attr_list , class Z_attribute & attr ) ;
void syntheticAqaraSensor2 ( Z_attribute_list & attr_list , class Z_attribute & attr ) ;
void syntheticAqaraCubeOrButton ( Z_attribute_list & attr_list , class Z_attribute & attr ) ;
void syntheticAqaraVibration ( Z_attribute_list & attr_list , class Z_attribute & attr ) ;
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void syntheticAnalogValue ( Z_attribute_list & attr_list , class Z_attribute & attr ) ;
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// handle read attributes auto-responder
void autoResponder ( const uint16_t * attr_list_ids , size_t attr_len ) ;
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inline void setGroupId ( uint16_t groupid ) {
_groupaddr = groupid ;
}
inline void setClusterId ( uint16_t clusterid ) {
_cluster_id = clusterid ;
}
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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 ; }
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const SBuffer & getPayload ( void ) const {
return _payload ;
}
uint16_t getManufCode ( void ) const {
return _manuf_code ;
}
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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
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int32_t encodeSingleAttribute ( class SBuffer & buf , double val_d , const char * val_str , uint8_t attrtype ) {
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uint32_t len = Z_getDatatypeLen ( attrtype ) ; // pre-compute length, overloaded for variable length attributes
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uint32_t u32 = val_d ;
int32_t i32 = val_d ;
float f32 = val_d ;
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switch ( attrtype ) {
// unsigned 8
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case Zbool : // bool
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case Zuint8 : // uint8
case Zenum8 : // enum8
case Zdata8 : // data8
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case Zmap8 : // map8
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buf . add8 ( u32 ) ;
break ;
// unsigned 16
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case Zuint16 : // uint16
case Zenum16 : // enum16
case Zdata16 : // data16
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case Zmap16 : // map16
buf . add16 ( u32 ) ;
break ;
// unisgned 32
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case Zuint24 :
buf . add16 ( u32 ) ;
buf . add8 ( u32 > > 16 ) ;
break ;
// unisgned 24
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case Zuint32 : // uint32
case Zdata32 : // data32
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case Zmap32 : // map32
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case ZUTC : // UTC - epoch 32 bits, seconds since 1-Jan-2000
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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
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 ;
}
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return len ;
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}
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//
// parse a single attribute
//
// Input:
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// attr: attribute object to store to
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// 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
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uint32_t parseSingleAttribute ( Z_attribute & attr , const SBuffer & buf ,
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uint32_t offset , int32_t attrtype = - 1 ) {
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uint32_t i = offset ;
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if ( attrtype < 0 ) {
attrtype = buf . get8 ( i + + ) ;
}
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// fallback - enter a null value
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attr . setNone ( ) ; // set to null by default
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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 ) {
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attr . setUInt ( uint8_val ) ;
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}
}
break ;
case Zuint16 : // uint16
case Zenum16 : // enum16
{
uint16_t uint16_val = buf . get16 ( i ) ;
// i += 2;
if ( 0xFFFF ! = uint16_val ) {
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attr . setUInt ( uint16_val ) ;
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}
}
break ;
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case Zuint24 :
{
uint32_t uint24_val = buf . get16 ( i ) + ( buf . get8 ( i + 2 ) > > 16 ) ;
// i += 3;
if ( 0xFFFFFF ! = uint24_val ) {
attr . setUInt ( uint24_val ) ;
}
}
break ;
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case Zuint32 : // uint32
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case ZUTC : // UTC
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{
uint32_t uint32_val = buf . get32 ( i ) ;
// i += 4;
if ( 0xFFFFFFFF ! = uint32_val ) {
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attr . setUInt ( uint32_val ) ;
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}
}
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
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// print as HEX "0x...."
char hex [ 2 * len + 3 ] ;
snprintf_P ( hex , sizeof ( hex ) , PSTR ( " 0x " ) ) ;
for ( uint32_t j = 0 ; j < len ; j + + ) {
snprintf_P ( hex , sizeof ( hex ) , PSTR ( " %s%02X " ) , hex , buf . get8 ( i + len - j - 1 ) ) ;
}
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attr . setStr ( hex ) ;
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// i += len;
}
break ;
case Zint8 : // int8
{
int8_t int8_val = buf . get8 ( i ) ;
// i += 1;
if ( 0x80 ! = int8_val ) {
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attr . setInt ( int8_val ) ;
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}
}
break ;
case Zint16 : // int16
{
int16_t int16_val = buf . get16 ( i ) ;
// i += 2;
if ( 0x8000 ! = int16_val ) {
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attr . setInt ( int16_val ) ;
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}
}
break ;
case Zint32 : // int32
{
int32_t int32_val = buf . get32 ( i ) ;
// i += 4;
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if ( - 0x80000000 ! = int32_val ) {
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attr . setInt ( int32_val ) ;
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}
}
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 ;
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len = ( attrtype < = Zstring ) ? buf . get8 ( i ) : buf . get16 ( i ) ; // len is 8 or 16 bits
i + = ( attrtype < = Zstring ) ? 1 : 2 ; // increment pointer
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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
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if ( ( Zoctstr = = attrtype ) | | ( Zoctstr16 = = attrtype ) ) { parse_as_string = false ; }
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if ( parse_as_string ) {
char str [ len + 1 ] ;
strncpy ( str , buf . charptr ( i ) , len ) ;
str [ len ] = 0x00 ;
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attr . setStr ( str ) ;
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} else {
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attr . setBuf ( buf , i , len ) ;
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}
// i += len;
// break;
}
// i += buf.get8(i) + 1;
break ;
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case Zstruct :
{
uint16_t struct_size = buf . get16 ( i ) ;
len = 2 ;
if ( 0xFFFF ! = struct_size ) {
if ( struct_size > 16 ) { struct_size = 16 ; }
// parse inner attributes - supports only fixed length for now
for ( uint32_t j = 0 ; j < struct_size ; j + + ) {
uint8_t attr_type = buf . get8 ( i + len ) ;
len + = Z_getDatatypeLen ( attr_type ) + 1 ;
}
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attr . setBuf ( buf , i , len ) ;
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}
}
break ;
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case Zdata8 : // data8
case Zmap8 : // map8
{
uint8_t uint8_val = buf . get8 ( i ) ;
// i += 1;
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attr . setUInt ( uint8_val ) ;
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}
break ;
case Zdata16 : // data16
case Zmap16 : // map16
{
uint16_t uint16_val = buf . get16 ( i ) ;
// i += 2;
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attr . setUInt ( uint16_val ) ;
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}
break ;
case Zdata32 : // data32
case Zmap32 : // map32
{
uint32_t uint32_val = buf . get32 ( i ) ;
// i += 4;
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attr . setUInt ( uint32_val ) ;
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}
break ;
case Zsingle : // float
{
uint32_t uint32_val = buf . get32 ( i ) ;
float * float_val = ( float * ) & uint32_val ;
// i += 4;
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attr . setFloat ( * float_val ) ;
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}
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;
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attr . setFloat ( ( float ) * double_val ) ;
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}
break ;
}
i + = len ;
return i - offset ; // how much have we increased the index
}
// First pass, parse all attributes in their native format
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void ZCLFrame : : parseReportAttributes ( Z_attribute_list & attr_list ) {
uint32_t i = 0 ;
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uint32_t len = _payload . len ( ) ;
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if ( ZCL_WRITE_ATTRIBUTES = = getCmdId ( ) ) {
attr_list . addAttribute ( PSTR ( " Command " ) , true ) . setStr ( PSTR ( " Write " ) ) ;
}
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while ( len > = i + 3 ) {
uint16_t attrid = _payload . get16 ( i ) ;
i + = 2 ;
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// 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
}
}
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// TODO look for suffix
Z_attribute & attr = attr_list . addAttribute ( _cluster_id , attrid ) ;
i + = parseSingleAttribute ( attr , _payload , i ) ;
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}
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// Issue Philips outdoor motion sensor SML002, see https://github.com/Koenkk/zigbee2mqtt/issues/897
// The sensor expects the coordinator to send a Default Response to acknowledge the attribute reporting
if ( 0 = = _frame_control . b . disable_def_resp ) {
// the device expects a default response
SBuffer buf ( 2 ) ;
buf . add8 ( _cmd_id ) ;
buf . add8 ( 0x00 ) ; // Status = OK
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ZigbeeZCLSend_Raw ( ZigbeeZCLSendMessage ( {
_srcaddr ,
0x0000 ,
_cluster_id ,
_srcendpoint ,
ZCL_DEFAULT_RESPONSE ,
_manuf_code ,
false /* not cluster specific */ ,
false /* noresponse */ ,
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true /* direct no retry */ ,
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_transact_seq , /* zcl transaction id */
buf . getBuffer ( ) , buf . len ( )
} ) ) ;
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}
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}
2020-04-16 18:36:14 +01:00
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//
// Extract attributes hidden in other compound attributes
//
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void ZCLFrame : : generateSyntheticAttributes ( Z_attribute_list & attr_list ) {
// scan through attributes and apply specific converters
for ( auto & attr : attr_list ) {
if ( attr . key_is_str ) { continue ; } // pass if key is a name
uint32_t ccccaaaa = ( attr . key . id . cluster < < 16 ) | attr . key . id . attr_id ;
switch ( ccccaaaa ) { // 0xccccaaaa . c=cluster, a=attribute
case 0x0000FF01 :
syntheticAqaraSensor ( attr_list , attr ) ;
break ;
case 0x0000FF02 :
syntheticAqaraSensor2 ( attr_list , attr ) ;
break ;
case 0x00120055 :
syntheticAqaraCubeOrButton ( attr_list , attr ) ;
break ;
case 0x01010055 :
case 0x01010508 :
syntheticAqaraVibration ( attr_list , attr ) ;
break ;
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case 0x000C0055 : // Analog Value
syntheticAnalogValue ( attr_list , attr ) ;
break ;
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}
}
}
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//
// Remove invalid values
//
void ZCLFrame : : removeInvalidAttributes ( Z_attribute_list & attr_list ) {
// scan through attributes and apply specific converters
for ( auto & attr : attr_list ) {
if ( attr . key_is_str ) { continue ; } // pass if key is a name
uint32_t ccccaaaa = ( attr . key . id . cluster < < 16 ) | attr . key . id . attr_id ;
switch ( ccccaaaa ) { // 0xccccaaaa . c=cluster, a=attribute
case 0x04020000 : // Temperature
if ( attr . getInt ( ) < = - 10000 ) {
// #9978, remove temperature of -100.00°C sent by lumi.weather
attr_list . removeAttribute ( & attr ) ;
}
break ;
}
}
}
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//
// Compute new attributes based on the standard set
// Note: both function are now split to compute on extracted attributes
//
void ZCLFrame : : computeSyntheticAttributes ( Z_attribute_list & attr_list ) {
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const Z_Device & device = zigbee_devices . findShortAddr ( _srcaddr ) ;
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const char * model_c = zigbee_devices . getModelId ( _srcaddr ) ; // null if unknown
String modelId ( ( char * ) model_c ) ;
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// scan through attributes and apply specific converters
for ( auto & attr : attr_list ) {
if ( attr . key_is_str ) { continue ; } // pass if key is a name
uint32_t ccccaaaa = ( attr . key . id . cluster < < 16 ) | attr . key . id . attr_id ;
switch ( ccccaaaa ) { // 0xccccaaaa . c=cluster, a=attribute
case 0x00010020 : // BatteryVoltage
if ( attr_list . countAttribute ( 0x0001 , 0x0021 ) = = 0 ) { // if it does not already contain BatteryPercentage
uint32_t mv = attr . getUInt ( ) * 100 ;
attr_list . addAttribute ( 0x0001 , 0x0021 ) . setUInt ( toPercentageCR2032 ( mv ) * 2 ) ;
}
break ;
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case 0x00010021 : // BatteryPercentage
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if ( modelId . startsWith ( F ( " TRADFRI " ) ) ) {
attr . setUInt ( attr . getUInt ( ) * 2 ) ; // bug in TRADFRI battery, need to double the value
}
break ;
case 0x00060000 : // "Power" for lumi Door/Window is converted to "Contact"
if ( modelId . startsWith ( F ( " lumi.sensor_magnet " ) ) ) {
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attr . setKeyId ( 0x0500 , 0xFFF0 + ZA_Contact ) ; // change cluster and attribute to 0500/FFF0
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}
break ;
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case 0x02010008 : // Pi Heating Demand - solve Eutotronic bug
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case 0x02014008 : // Eurotronic Host Flags decoding
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{
const char * manufacturer_c = zigbee_devices . getManufacturerId ( _srcaddr ) ; // null if unknown
String manufacturerId ( ( char * ) manufacturer_c ) ;
if ( manufacturerId . equals ( F ( " Eurotronic " ) ) ) {
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if ( ccccaaaa = = 0x02010008 ) {
// Eurotronic does not report 0..100 but 0..255, including 255 which is normally an ivalid value
uint8_t valve = attr . getUInt ( ) ;
if ( attr . isNone ( ) ) { valve = 255 ; }
uint8_t valve_100 = changeUIntScale ( valve , 0 , 255 , 0 , 100 ) ;
attr . setUInt ( valve_100 ) ;
} else if ( ccccaaaa = = 0x02014008 ) {
uint32_t mode = attr . getUInt ( ) ;
if ( mode & 0x02 ) { attr_list . addAttribute ( 0x0201 , 0xF002 ) . setUInt ( 1 ) ; }
if ( mode & 0x04 ) { attr_list . addAttribute ( 0x0201 , 0xF004 ) . setUInt ( 1 ) ; }
if ( mode & 0x10 ) { attr_list . addAttribute ( 0x0201 , 0xF010 ) . setUInt ( 1 ) ; }
if ( mode & 0x80 ) { attr_list . addAttribute ( 0x0201 , 0xF080 ) . setUInt ( 1 ) ; }
}
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}
}
break ;
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case 0x03000000 : // Hue
case 0x03000001 : // Sat
case 0x03000003 : // X
case 0x03000004 : // Y
{ // generate synthetic RGB
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const Z_attribute * attr_rgb = attr_list . findAttribute ( PSTR ( " RGB " ) ) ;
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if ( attr_rgb = = nullptr ) { // make sure we didn't already computed it
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uint8_t brightness = 255 ;
if ( device . valid ( ) ) {
const Z_Data_Light & light = device . data . find < Z_Data_Light > ( _srcendpoint ) ;
if ( ( & light ! = nullptr ) & & ( light . validDimmer ( ) ) ) {
// Dimmer has a valid value
brightness = changeUIntScale ( light . getDimmer ( ) , 0 , 254 , 0 , 255 ) ; // range is 0..255
}
}
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const Z_attribute * attr_hue = attr_list . findAttribute ( 0x0300 , 0x0000 ) ;
const Z_attribute * attr_sat = attr_list . findAttribute ( 0x0300 , 0x0001 ) ;
const Z_attribute * attr_x = attr_list . findAttribute ( 0x0300 , 0x0003 ) ;
const Z_attribute * attr_y = attr_list . findAttribute ( 0x0300 , 0x0004 ) ;
if ( attr_hue & & attr_sat ) {
uint8_t sat = changeUIntScale ( attr_sat - > getUInt ( ) , 0 , 254 , 0 , 255 ) ;
2021-01-17 17:51:22 +00:00
uint16_t hue = changeUIntScale ( attr_hue - > getUInt ( ) , 0 , 254 , 0 , 360 ) ;
Z_Data_Light : : toRGBAttributesHSB ( attr_list , hue , sat , brightness ) ;
} else if ( attr_x & & attr_y ) {
Z_Data_Light : : toRGBAttributesXYB ( attr_list , attr_x - > getUInt ( ) , attr_y - > getUInt ( ) , brightness ) ;
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}
}
}
break ;
case 0x04030000 : // SeaPressure
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{
int16_t pressure = attr . getInt ( ) ;
int16_t pressure_sealevel = ( pressure / FastPrecisePow ( 1.0 - ( ( float ) Settings . altitude / 44330.0f ) , 5.255f ) ) - 21.6f ;
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attr_list . addAttribute ( 0x0403 , 0xFFF0 ) . setInt ( pressure_sealevel ) ;
// We create a synthetic attribute 0403/FFF0 to indicate sea level
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}
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break ;
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case 0x05000002 : // ZoneStatus
const Z_Data_Alarm & alarm = ( const Z_Data_Alarm & ) zigbee_devices . getShortAddr ( _srcaddr ) . data . find ( Z_Data_Type : : Z_Alarm , _srcendpoint ) ;
if ( & alarm ! = nullptr ) {
alarm . convertZoneStatus ( attr_list , attr . getUInt ( ) ) ;
}
break ;
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}
}
}
2020-09-05 13:44:31 +01:00
// Set deferred callbacks for Occupancy
// TODO make delay a parameter
void ZCLFrame : : generateCallBacks ( Z_attribute_list & attr_list ) {
static const uint32_t OCCUPANCY_TIMEOUT = 90 * 1000 ; // 90 s
// scan through attributes and apply specific converters
for ( auto & attr : attr_list ) {
if ( attr . key_is_str ) { continue ; } // pass if key is a name
uint32_t ccccaaaa = ( attr . key . id . cluster < < 16 ) | attr . key . id . attr_id ;
switch ( ccccaaaa ) { // 0xccccaaaa . c=cluster, a=attribute
case 0x04060000 : // Occupancy
uint32_t occupancy = attr . getUInt ( ) ;
if ( occupancy ) {
2020-10-31 16:48:40 +00:00
uint32_t pir_timer = OCCUPANCY_TIMEOUT ;
const Z_Data_PIR & pir_found = ( const Z_Data_PIR & ) zigbee_devices . getShortAddr ( _srcaddr ) . data . find ( Z_Data_Type : : Z_PIR , _srcendpoint ) ;
if ( & pir_found ! = nullptr ) {
pir_timer = pir_found . getTimeoutSeconds ( ) * 1000 ;
}
2020-11-09 10:56:29 +00:00
if ( pir_timer > 0 ) {
zigbee_devices . setTimer ( _srcaddr , 0 /* groupaddr */ , pir_timer , _cluster_id , _srcendpoint , Z_CAT_VIRTUAL_OCCUPANCY , 0 , & Z_OccupancyCallback ) ;
}
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} else {
zigbee_devices . resetTimersForDevice ( _srcaddr , 0 /* groupaddr */ , Z_CAT_VIRTUAL_OCCUPANCY ) ;
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}
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break ;
}
}
}
2020-09-06 19:51:20 +01:00
// A command has been sent to a device this device, or to a group
// Set timers to read back values.
// If it's a device address, also set a timer for reachability test
void sendHueUpdate ( uint16_t shortaddr , uint16_t groupaddr , uint16_t cluster , uint8_t endpoint = 0 ) {
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uint32_t wait_ms = 0xFFFF ;
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switch ( cluster ) {
case 0x0006 :
wait_ms = 200 ; // wait 0.2 s
break ;
case 0x0008 :
wait_ms = 1050 ; // wait 1.0 s
break ;
case 0x0102 :
wait_ms = 10000 ; // wait 10.0 s
break ;
case 0x0300 :
wait_ms = 1050 ; // wait 1.0 s
break ;
default :
break ;
}
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if ( 0xFFFF ! = wait_ms ) {
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if ( ( BAD_SHORTADDR ! = shortaddr ) & & ( 0 = = endpoint ) ) {
endpoint = zigbee_devices . findFirstEndpoint ( shortaddr ) ;
}
if ( ( BAD_SHORTADDR = = shortaddr ) | | ( endpoint ) ) { // send if group address or endpoint is known
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zigbee_devices . queueTimer ( shortaddr , groupaddr , wait_ms , cluster , endpoint , Z_CAT_READ_CLUSTER , 0 /* value */ , & Z_ReadAttrCallback ) ;
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if ( BAD_SHORTADDR ! = shortaddr ) { // reachability test is not possible for group addresses, since we don't know the list of devices in the group
zigbee_devices . setTimer ( shortaddr , groupaddr , wait_ms + Z_CAT_REACHABILITY_TIMEOUT , cluster , endpoint , Z_CAT_REACHABILITY , 0 /* value */ , & Z_Unreachable ) ;
}
}
}
}
2020-05-29 21:52:45 +01:00
// ZCL_READ_ATTRIBUTES
2020-09-05 13:44:31 +01:00
void ZCLFrame : : parseReadAttributes ( Z_attribute_list & attr_list ) {
uint32_t i = 0 ;
2020-05-29 21:52:45 +01:00
uint32_t len = _payload . len ( ) ;
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2020-09-05 13:44:31 +01:00
uint16_t read_attr_ids [ len / 2 ] ;
2020-11-30 18:25:05 +00:00
attr_list . addAttributePMEM ( PSTR ( D_CMND_ZIGBEE_CLUSTER ) ) . setUInt ( _cluster_id ) ;
2020-04-16 18:36:14 +01:00
2020-10-28 09:08:15 +00:00
JsonGeneratorArray attr_numbers ;
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Z_attribute_list attr_names ;
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while ( len > = 2 + i ) {
2020-05-29 21:52:45 +01:00
uint16_t attrid = _payload . get16 ( i ) ;
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attr_numbers . add ( attrid ) ;
read_attr_ids [ i / 2 ] = attrid ;
2020-04-25 10:37:36 +01:00
2020-05-29 21:52:45 +01:00
// 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 ) ;
2019-10-20 15:43:50 +01:00
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if ( ( conv_cluster = = _cluster_id ) & & ( conv_attribute = = attrid ) ) {
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attr_names . addAttribute ( Z_strings + pgm_read_word ( & converter - > name_offset ) , true ) . setBool ( true ) ;
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break ;
}
}
i + = 2 ;
}
2020-11-30 18:25:05 +00:00
attr_list . addAttributePMEM ( PSTR ( " Read " ) ) . setStrRaw ( attr_numbers . toString ( ) . c_str ( ) ) ;
attr_list . addAttributePMEM ( PSTR ( " ReadNames " ) ) . setStrRaw ( attr_names . toString ( true ) . c_str ( ) ) ;
2020-10-30 11:29:48 +00:00
2020-09-05 13:44:31 +01:00
// call auto-responder
2020-10-19 19:34:40 +01:00
autoResponder ( read_attr_ids , len / 2 ) ;
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}
2019-11-03 11:41:44 +00:00
2020-08-08 11:17:37 +01:00
// ZCL_CONFIGURE_REPORTING_RESPONSE
2020-09-05 13:44:31 +01:00
void ZCLFrame : : parseConfigAttributes ( Z_attribute_list & attr_list ) {
2020-08-08 11:17:37 +01:00
uint32_t len = _payload . len ( ) ;
2020-09-05 13:44:31 +01:00
2020-09-12 09:57:54 +01:00
Z_attribute_list attr_config_list ;
for ( uint32_t i = 0 ; len > = i + 4 ; i + = 4 ) {
uint8_t status = _payload . get8 ( i ) ;
uint16_t attr_id = _payload . get8 ( i + 2 ) ;
Z_attribute_list attr_config_response ;
2020-11-30 18:25:05 +00:00
attr_config_response . addAttributePMEM ( PSTR ( " Status " ) ) . setUInt ( status ) ;
attr_config_response . addAttributePMEM ( PSTR ( " StatusMsg " ) ) . setStr ( getZigbeeStatusMessage ( status ) . c_str ( ) ) ;
2020-09-12 09:57:54 +01:00
const __FlashStringHelper * attr_name = zigbeeFindAttributeById ( _cluster_id , attr_id , nullptr , nullptr ) ;
if ( attr_name ) {
attr_config_list . addAttribute ( attr_name ) . setStrRaw ( attr_config_response . toString ( true ) . c_str ( ) ) ;
} else {
attr_config_list . addAttribute ( _cluster_id , attr_id ) . setStrRaw ( attr_config_response . toString ( true ) . c_str ( ) ) ;
}
}
2020-09-05 13:44:31 +01:00
2020-11-30 18:25:05 +00:00
Z_attribute & attr_1 = attr_list . addAttributePMEM ( PSTR ( " ConfigResponse " ) ) ;
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attr_1 . setStrRaw ( attr_config_list . toString ( true ) . c_str ( ) ) ;
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}
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// ZCL_WRITE_ATTRIBUTES_RESPONSE
void ZCLFrame : : parseWriteAttributesResponse ( Z_attribute_list & attr_list ) {
parseResponse_inner ( ZCL_WRITE_ATTRIBUTES_RESPONSE , false , _payload . get8 ( 0 ) ) ;
}
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// ZCL_READ_REPORTING_CONFIGURATION_RESPONSE
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void ZCLFrame : : parseReadConfigAttributes ( Z_attribute_list & attr_list ) {
uint32_t i = 0 ;
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uint32_t len = _payload . len ( ) ;
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Z_attribute & attr_root = attr_list . addAttributePMEM ( PSTR ( " ReadConfig " ) ) ;
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Z_attribute_list attr_1 ;
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while ( len > = i + 4 ) {
uint8_t status = _payload . get8 ( i ) ;
uint8_t direction = _payload . get8 ( i + 1 ) ;
uint16_t attrid = _payload . get16 ( i + 2 ) ;
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Z_attribute_list attr_2 ;
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if ( direction ) {
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attr_2 . addAttributePMEM ( PSTR ( " DirectionReceived " ) ) . setBool ( true ) ;
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}
// find the attribute name
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int8_t multiplier = 1 ;
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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 ) ) {
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const char * attr_name = Z_strings + pgm_read_word ( & converter - > name_offset ) ;
attr_2 . addAttribute ( attr_name , true ) . setBool ( true ) ;
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multiplier = CmToMultiplier ( pgm_read_byte ( & converter - > multiplier_idx ) ) ;
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break ;
}
}
i + = 4 ;
if ( 0 ! = status ) {
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attr_2 . addAttributePMEM ( PSTR ( " Status " ) ) . setUInt ( status ) ;
attr_2 . addAttributePMEM ( PSTR ( " StatusMsg " ) ) . setStr ( getZigbeeStatusMessage ( status ) . c_str ( ) ) ;
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} else {
// no error, decode data
if ( direction ) {
// only Timeout period is present
uint16_t attr_timeout = _payload . get16 ( i ) ;
i + = 2 ;
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attr_2 . addAttributePMEM ( PSTR ( " TimeoutPeriod " ) ) . setUInt ( ( 0xFFFF = = attr_timeout ) ? - 1 : attr_timeout ) ;
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} 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 ;
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attr_2 . addAttributePMEM ( PSTR ( " MinInterval " ) ) . setUInt ( ( 0xFFFF = = attr_min_interval ) ? - 1 : attr_min_interval ) ;
attr_2 . addAttributePMEM ( PSTR ( " MaxInterval " ) ) . setUInt ( ( 0xFFFF = = attr_max_interval ) ? - 1 : attr_max_interval ) ;
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if ( ! attr_discrete ) {
// decode Reportable Change
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Z_attribute & attr_change = attr_2 . addAttributePMEM ( PSTR ( " ReportableChange " ) ) ;
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i + = parseSingleAttribute ( attr_change , _payload , i , attr_type ) ;
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if ( ( 1 ! = multiplier ) & & ( 0 ! = multiplier ) ) {
float fval = attr_change . getFloat ( ) ;
if ( multiplier > 0 ) { fval = fval * multiplier ; }
else { fval = fval / ( - multiplier ) ; }
attr_change . setFloat ( fval ) ;
}
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}
}
}
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attr_1 . addAttribute ( _cluster_id , attrid ) . setStrRaw ( attr_2 . toString ( true ) . c_str ( ) ) ;
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}
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attr_root . setStrRaw ( attr_1 . toString ( true ) . c_str ( ) ) ;
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}
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// ZCL_READ_ATTRIBUTES_RESPONSE
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void ZCLFrame : : parseReadAttributesResponse ( Z_attribute_list & attr_list ) {
uint32_t i = 0 ;
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uint32_t len = _payload . len ( ) ;
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while ( len > = i + 4 ) {
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uint16_t attrid = _payload . get16 ( i ) ;
i + = 2 ;
uint8_t status = _payload . get8 ( i + + ) ;
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if ( 0 = = status ) {
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Z_attribute & attr = attr_list . addAttribute ( _cluster_id , attrid ) ;
i + = parseSingleAttribute ( attr , _payload , i ) ;
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}
}
}
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void ZCLFrame : : parseResponse_inner ( uint8_t cmd , bool cluster_specific , uint8_t status ) {
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Z_attribute_list attr_list ;
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// "Device"
char s [ 12 ] ;
snprintf_P ( s , sizeof ( s ) , PSTR ( " 0x%04X " ) , _srcaddr ) ;
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attr_list . addAttributePMEM ( PSTR ( D_JSON_ZIGBEE_DEVICE ) ) . setStr ( s ) ;
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// "Name"
const char * friendlyName = zigbee_devices . getFriendlyName ( _srcaddr ) ;
if ( friendlyName ) {
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attr_list . addAttributePMEM ( PSTR ( D_JSON_ZIGBEE_NAME ) ) . setStr ( friendlyName ) ;
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}
// "Command"
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snprintf_P ( s , sizeof ( s ) , PSTR ( " %04X%c%02X " ) , _cluster_id , cluster_specific ? ' ! ' : ' _ ' , cmd ) ;
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attr_list . addAttributePMEM ( PSTR ( D_JSON_ZIGBEE_CMD ) ) . setStr ( s ) ;
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// "Status"
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attr_list . addAttributePMEM ( PSTR ( D_JSON_ZIGBEE_STATUS ) ) . setUInt ( status ) ;
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// "StatusMessage"
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attr_list . addAttributePMEM ( PSTR ( D_JSON_ZIGBEE_STATUS_MSG ) ) . setStr ( getZigbeeStatusMessage ( status ) . c_str ( ) ) ;
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// Add Endpoint
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attr_list . addAttributePMEM ( PSTR ( D_CMND_ZIGBEE_ENDPOINT ) ) . setUInt ( _srcendpoint ) ;
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// Add Group if non-zero
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if ( _groupaddr ) { // TODO what about group zero
attr_list . group_id = _groupaddr ;
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}
// Add linkquality
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attr_list . lqi = _linkquality ;
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Response_P ( PSTR ( " { \" " D_JSON_ZIGBEE_RESPONSE " \" :%s} " ) , attr_list . toString ( true ) . c_str ( ) ) ;
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MqttPublishPrefixTopicRulesProcess_P ( RESULT_OR_TELE , PSTR ( D_JSON_ZIGBEEZCL_RECEIVED ) ) ;
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}
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// 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 ) ;
parseResponse_inner ( cmd , true , status ) ;
}
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/*********************************************************************************************\
* Callbacks
\ * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
// Reset the debounce marker
void Z_ResetDebounce ( uint16_t shortaddr , uint16_t groupaddr , uint16_t cluster , uint8_t endpoint , uint32_t value ) {
zigbee_devices . getShortAddr ( shortaddr ) . debounce_endpoint = 0 ;
}
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// Parse non-normalized attributes
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void ZCLFrame : : parseClusterSpecificCommand ( Z_attribute_list & attr_list ) {
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// Check if debounce is active and if the packet is a duplicate
Z_Device & device = zigbee_devices . getShortAddr ( _srcaddr ) ;
if ( ( device . debounce_endpoint ! = 0 ) & & ( device . debounce_endpoint = = _srcendpoint ) & & ( device . debounce_transact = = _transact_seq ) ) {
// this is a duplicate, drop the packet
AddLog_P ( LOG_LEVEL_DEBUG , PSTR ( D_LOG_ZIGBEE " Discarding duplicate command from 0x%04X, endpoint %d " ) , _srcaddr , _srcendpoint ) ;
} else {
// reset the duplicate marker, parse the packet normally, and set a timer to reset the marker later (which will discard any existing timer for the same device/endpoint)
device . debounce_endpoint = _srcendpoint ;
device . debounce_transact = _transact_seq ;
zigbee_devices . setTimer ( _srcaddr , 0 /* groupaddr */ , USE_ZIGBEE_DEBOUNCE_COMMANDS , 0 /*clusterid*/ , _srcendpoint , Z_CAT_DEBOUNCE_CMD , 0 , & Z_ResetDebounce ) ;
convertClusterSpecific ( attr_list , _cluster_id , _cmd_id , _frame_control . b . direction , _srcaddr , _srcendpoint , _payload ) ;
if ( ! Settings . flag5 . zb_disable_autoquery ) {
// read attributes unless disabled
if ( ! _frame_control . b . direction ) { // only handle server->client (i.e. device->coordinator)
if ( _wasbroadcast ) { // only update for broadcast messages since we don't see unicast from device to device and we wouldn't know the target
sendHueUpdate ( BAD_SHORTADDR , _groupaddr , _cluster_id ) ;
}
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}
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}
}
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// Send Default Response to acknowledge the attribute reporting
if ( 0 = = _frame_control . b . disable_def_resp ) {
// the device expects a default response
SBuffer buf ( 2 ) ;
buf . add8 ( _cmd_id ) ;
buf . add8 ( 0x00 ) ; // Status = OK
ZigbeeZCLSend_Raw ( ZigbeeZCLSendMessage ( {
_srcaddr ,
0x0000 ,
_cluster_id ,
_srcendpoint ,
ZCL_DEFAULT_RESPONSE ,
_manuf_code ,
false /* not cluster specific */ ,
false /* noresponse */ ,
true /* direct no retry */ ,
_transact_seq , /* zcl transaction id */
buf . getBuffer ( ) , buf . len ( )
} ) ) ;
}
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}
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// ======================================================================
// Convert AnalogValue according to the device type
void ZCLFrame : : syntheticAnalogValue ( Z_attribute_list & attr_list , class Z_attribute & attr ) {
const char * modelId_c = zigbee_devices . getModelId ( _srcaddr ) ; // null if unknown
String modelId ( ( char * ) modelId_c ) ;
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if ( modelId . startsWith ( F ( " lumi.sensor_cube " ) ) ) {
attr . setKeyId ( 0x000C , 0xFF55 ) ; // change to AqaraRotate
}
if ( modelId . startsWith ( F ( " lumi.plug " ) ) ) {
attr . setKeyId ( 0x0702 , 0x0000 ) ; // change to EnergyTotal
}
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if ( modelId . startsWith ( F ( " lumi.ctrl " ) ) ) {
attr . setKeyId ( 0x0B04 , 0x050B ) ; // change to ActivePower
}
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}
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// ======================================================================
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// New version of synthetic attribute generation
void ZCLFrame : : syntheticAqaraSensor ( Z_attribute_list & attr_list , class Z_attribute & attr ) {
const SBuffer * buf = attr . getRaw ( ) ;
if ( buf ) {
const SBuffer & buf2 = * buf ;
uint32_t i = 0 ;
uint32_t len = buf2 . len ( ) ;
const char * modelId_c = zigbee_devices . getModelId ( _srcaddr ) ; // null if unknown
String modelId ( ( char * ) modelId_c ) ;
while ( len > = 2 + i ) {
uint8_t attrid = buf2 . get8 ( i + + ) ;
Z_attribute attr ; // temporary attribute
i + = parseSingleAttribute ( attr , buf2 , i ) ;
int32_t ival32 = attr . getInt ( ) ;
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uint32_t uval32 = attr . getUInt ( ) ;
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bool translated = false ; // were we able to translate to a known format?
if ( 0x01 = = attrid ) {
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float batteryvoltage = attr . getFloat ( ) / 100 ;
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attr_list . addAttribute ( 0x0001 , 0x0020 ) . setFloat ( batteryvoltage ) ;
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uint8_t batterypercentage = toPercentageCR2032 ( uval32 ) ;
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attr_list . addAttribute ( 0x0001 , 0x0021 ) . setUInt ( batterypercentage * 2 ) ;
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} else if ( ( nullptr ! = modelId ) & & ( ( 0 = = getManufCode ( ) ) | | ( 0x115F = = getManufCode ( ) ) ) ) {
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translated = true ;
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if ( modelId . startsWith ( F ( " lumi.sensor_magnet " ) ) ) { // door / window sensor
if ( 0x64 = = attrid ) {
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attr_list . addAttribute ( 0x0500 , 0xFFF0 + ZA_Contact ) . copyVal ( attr ) ; // Contact
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}
} else if ( modelId . startsWith ( F ( " lumi.sensor_smoke " ) ) ) { // gas leak
if ( 0x64 = = attrid ) {
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attr_list . addAttributePMEM ( PSTR ( " SmokeDensity " ) ) . copyVal ( attr ) ;
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}
} else if ( modelId . startsWith ( F ( " lumi.sensor_natgas " ) ) ) { // gas leak
if ( 0x64 = = attrid ) {
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attr_list . addAttributePMEM ( PSTR ( " GasDensity " ) ) . copyVal ( attr ) ;
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}
} else if ( modelId . startsWith ( F ( " lumi.sensor_ht " ) ) | |
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modelId . equals ( F ( " lumi.sens " ) ) | |
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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 ) {
attr_list . addAttribute ( 0x0402 , 0x0000 ) . setInt ( ival32 ) ; // Temperature
} else if ( 0x65 = = attrid ) {
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attr_list . addAttribute ( 0x0405 , 0x0000 ) . setUInt ( uval32 ) ; // Humidity * 100
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} else if ( 0x66 = = attrid ) {
attr_list . addAttribute ( 0x0403 , 0x0000 ) . setUInt ( ( ival32 + 50 ) / 100 ) ; // Pressure
}
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} else if ( modelId . startsWith ( F ( " lumi.plug " ) ) | | modelId . startsWith ( F ( " lumi.ctrl " ) ) ) {
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if ( 0x64 = = attrid ) {
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attr_list . addAttribute ( 0x0006 , 0x0000 ) . setInt ( uval32 ) ; // Power (on/off)
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} else if ( 0x98 = = attrid ) {
attr_list . addAttribute ( 0x0B04 , 0x050B ) . setInt ( ival32 ) ; // Active Power
} else if ( 0x95 = = attrid ) {
attr_list . addAttribute ( 0x0702 , 0x0000 ) . setUInt ( uval32 ) ; // EnergyDelivered
}
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} else {
translated = false ; // we didn't find a match
}
}
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 ) ;
attr_list . addAttribute ( attr_name ) . copyVal ( attr ) ;
}
}
}
}
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}
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void ZCLFrame : : syntheticAqaraSensor2 ( class Z_attribute_list & attr_list , class Z_attribute & attr ) {
const SBuffer * buf = attr . getRaw ( ) ;
if ( buf ) {
const SBuffer & buf2 = * buf ;
uint32_t len = buf2 . len ( ) ;
// Look for battery value which is the first attribute of type 0x21
uint16_t struct_size = buf2 . get16 ( 0 ) ;
size_t struct_len = 2 ;
if ( 0xFFFF ! = struct_size ) {
if ( struct_size > 16 ) { struct_size = 16 ; }
for ( uint32_t j = 0 ; ( j < struct_size ) & & ( struct_len < len ) ; j + + ) {
uint8_t attr_type = buf2 . get8 ( struct_len ) ;
if ( 0x21 = = attr_type ) {
uint16_t val = buf2 . get16 ( struct_len + 1 ) ;
float batteryvoltage = ( float ) val / 100 ;
attr_list . addAttribute ( 0x0001 , 0x0020 ) . setFloat ( batteryvoltage ) ;
uint8_t batterypercentage = toPercentageCR2032 ( val ) ;
attr_list . addAttribute ( 0x0001 , 0x0021 ) . setUInt ( batterypercentage * 2 ) ;
break ;
}
struct_len + = Z_getDatatypeLen ( attr_type ) + 1 ;
}
}
}
attr_list . removeAttribute ( & attr ) ;
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}
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// Aqara Cube and Button
void ZCLFrame : : syntheticAqaraCubeOrButton ( class Z_attribute_list & attr_list , class Z_attribute & attr ) {
const char * modelId_c = zigbee_devices . findShortAddr ( _srcaddr ) . modelId ; // null if unknown
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String modelId ( ( char * ) modelId_c ) ;
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if ( modelId . startsWith ( F ( " lumi.sensor_cube " ) ) ) { // only for Aqara cube
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int32_t val = attr . getInt ( ) ;
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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 :
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attr_list . addAttribute ( aqara_cube ) . setStr ( PSTR ( " shake " ) ) ;
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break ;
case 2 :
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attr_list . addAttribute ( aqara_cube ) . setStr ( PSTR ( " wakeup " ) ) ;
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break ;
case 3 :
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attr_list . addAttribute ( aqara_cube ) . setStr ( PSTR ( " fall " ) ) ;
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break ;
case 64 . . . 127 :
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attr_list . addAttribute ( aqara_cube ) . setStr ( PSTR ( " flip90 " ) ) ;
attr_list . addAttribute ( aqara_cube_side ) . setInt ( val % 8 ) ;
attr_list . addAttribute ( aqara_cube_from_side ) . setInt ( ( val - 64 ) / 8 ) ;
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break ;
case 128 . . . 132 :
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attr_list . addAttribute ( aqara_cube ) . setStr ( PSTR ( " flip180 " ) ) ;
attr_list . addAttribute ( aqara_cube_side ) . setInt ( val - 128 ) ;
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break ;
case 256 . . . 261 :
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attr_list . addAttribute ( aqara_cube ) . setStr ( PSTR ( " slide " ) ) ;
attr_list . addAttribute ( aqara_cube_side ) . setInt ( val - 256 ) ;
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break ;
case 512 . . . 517 :
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attr_list . addAttribute ( aqara_cube ) . setStr ( PSTR ( " tap " ) ) ;
attr_list . addAttribute ( aqara_cube_side ) . setInt ( val - 512 ) ;
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break ;
}
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attr_list . removeAttribute ( & attr ) ;
// 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
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} else if ( modelId . startsWith ( F ( " lumi.remote " ) ) | | modelId . startsWith ( F ( " lumi.sensor_swit " ) ) ) { // only for Aqara buttons WXKG11LM & WXKG12LM, 'swit' because of #9923
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int32_t val = attr . getInt ( ) ;
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const __FlashStringHelper * aqara_click = F ( " click " ) ; // deprecated
const __FlashStringHelper * aqara_action = F ( " action " ) ; // deprecated
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Z_attribute & attr_click = attr_list . addAttribute ( PSTR ( " Click " ) , true ) ;
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switch ( val ) {
case 0 :
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attr_list . addAttribute ( aqara_action ) . setStr ( PSTR ( " hold " ) ) ; // deprecated
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attr_click . setStr ( PSTR ( " hold " ) ) ;
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break ;
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case 1 :
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attr_list . addAttribute ( aqara_click ) . setStr ( PSTR ( " single " ) ) ; // deprecated
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attr_click . setStr ( PSTR ( " single " ) ) ;
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break ;
case 2 :
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attr_list . addAttribute ( aqara_click ) . setStr ( PSTR ( " double " ) ) ; // deprecated
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attr_click . setStr ( PSTR ( " double " ) ) ;
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break ;
case 3 :
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attr_click . setStr ( PSTR ( " triple " ) ) ;
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break ;
case 4 :
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attr_click . setStr ( PSTR ( " quadruple " ) ) ;
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break ;
case 16 :
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attr_list . addAttribute ( aqara_action ) . setStr ( PSTR ( " hold " ) ) ; // deprecated
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attr_click . setStr ( PSTR ( " hold " ) ) ;
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break ;
case 17 :
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attr_list . addAttribute ( aqara_action ) . setStr ( PSTR ( " release " ) ) ; // deprecated
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attr_click . setStr ( PSTR ( " release " ) ) ;
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break ;
case 18 :
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attr_list . addAttribute ( aqara_action ) . setStr ( PSTR ( " shake " ) ) ; // deprecated
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attr_click . setStr ( PSTR ( " shake " ) ) ;
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break ;
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case 255 :
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attr_list . addAttribute ( aqara_action ) . setStr ( PSTR ( " release " ) ) ; // deprecated
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attr_click . setStr ( PSTR ( " release " ) ) ;
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break ;
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default :
attr_list . addAttribute ( aqara_click ) . setUInt ( val ) ;
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attr_click . setStr ( PSTR ( " release " ) ) ;
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break ;
}
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}
}
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// Aqara vibration device
void ZCLFrame : : syntheticAqaraVibration ( class Z_attribute_list & attr_list , class Z_attribute & attr ) {
switch ( attr . key . id . attr_id ) {
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case 0x0055 :
{
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int32_t ivalue = attr . getInt ( ) ;
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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 ;
}
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attr . setStr ( ( const char * ) svalue ) ;
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}
break ;
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case 0x0503 :
break ;
case 0x0505 :
break ;
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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
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const SBuffer * buf = attr . getRaw ( ) ;
if ( buf ) {
const SBuffer & buf2 = * buf ;
int16_t x , y , z ;
z = buf2 . get16 ( 0 ) ;
y = buf2 . get16 ( 2 ) ;
x = buf2 . get16 ( 4 ) ;
char temp [ 32 ] ;
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snprintf_P ( temp , sizeof ( temp ) , PSTR ( " [%i,%i,%i] " ) , x , y , z ) ;
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attr . setStrRaw ( temp ) ;
// 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 ;
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snprintf_P ( temp , sizeof ( temp ) , PSTR ( " [%i,%i,%i] " ) , Angle_X , Angle_Y , Angle_Z ) ;
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attr_list . addAttributePMEM ( PSTR ( " AqaraAngles " ) ) . setStrRaw ( temp ) ;
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}
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}
break ;
}
}
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/// Publish a message for `"Occupancy":0` when the timer expired
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void Z_OccupancyCallback ( uint16_t shortaddr , uint16_t groupaddr , uint16_t cluster , uint8_t endpoint , uint32_t value ) {
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Z_attribute_list attr_list ;
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attr_list . addAttribute ( 0x0406 , 0x0000 ) . setUInt ( 0 ) ; // Occupancy
Z_postProcessAttributes ( shortaddr , endpoint , attr_list ) ; // make sure all is updated accordingly
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zigbee_devices . jsonPublishNow ( shortaddr , attr_list ) ;
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}
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// ======================================================================
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void Z_postProcessAttributes ( uint16_t shortaddr , uint16_t src_ep , class Z_attribute_list & attr_list ) {
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Z_Device & device = zigbee_devices . getShortAddr ( shortaddr ) ;
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uint8_t count_ep = device . countEndpoints ( ) ;
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for ( auto & attr : attr_list ) {
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// add endpoint suffix if needed
if ( ( Settings . flag4 . zb_index_ep ) & & ( src_ep ! = 1 ) & & ( count_ep > 1 ) ) {
// we need to add suffix if the suffix is not already different from 1
if ( attr . key_suffix = = 1 ) {
attr . key_suffix = src_ep ;
}
}
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// attr is Z_attribute&
if ( ! attr . key_is_str ) {
uint16_t cluster = attr . key . id . cluster ;
uint16_t attribute = attr . key . id . attr_id ;
uint32_t ccccaaaa = ( attr . key . id . cluster < < 16 ) | attr . key . id . attr_id ;
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// Look for an entry in the converter table
bool found = false ;
const char * conv_name ;
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Z_Data_Type map_type = Z_Data_Type : : Z_Unknown ;
uint8_t map_offset = 0 ;
uint8_t zigbee_type = Znodata ;
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int8_t conv_multiplier ;
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for ( uint32_t i = 0 ; i < ARRAY_SIZE ( Z_PostProcess ) ; i + + ) {
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const Z_AttributeConverter * converter = & Z_PostProcess [ i ] ;
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uint16_t conv_cluster = CxToCluster ( pgm_read_byte ( & converter - > cluster_short ) ) ;
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uint16_t conv_attribute = pgm_read_word ( & converter - > attribute ) ;
if ( ( conv_cluster = = cluster ) & &
( ( conv_attribute = = attribute ) | | ( conv_attribute = = 0xFFFF ) ) ) {
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conv_multiplier = CmToMultiplier ( pgm_read_byte ( & converter - > multiplier_idx ) ) ;
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zigbee_type = pgm_read_byte ( & converter - > type ) ;
uint8_t mapping = pgm_read_byte ( & converter - > mapping ) ;
map_type = ( Z_Data_Type ) ( ( mapping & 0xF0 ) > > 4 ) ;
map_offset = ( mapping & 0x0F ) ;
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conv_name = Z_strings + pgm_read_word ( & converter - > name_offset ) ;
found = true ;
break ;
}
}
float fval = attr . getFloat ( ) ;
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if ( found & & ( map_type ! = Z_Data_Type : : Z_Unknown ) ) {
// We apply an automatic mapping to Z_Data_XXX object
// First we find or instantiate the correct Z_Data_XXX accorfing to the endpoint
// Then store the attribute at the attribute addres (via offset) and according to size 8/16/32 bits
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// add the endpoint if it was not already known
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device . addEndpoint ( src_ep ) ;
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// we don't apply the multiplier, but instead store in Z_Data_XXX object
Z_Data & data = device . data . getByType ( map_type , src_ep ) ;
uint8_t * attr_address = ( ( uint8_t * ) & data ) + sizeof ( Z_Data ) + map_offset ;
uint32_t uval32 = attr . getUInt ( ) ; // call converter to uint only once
int32_t ival32 = attr . getInt ( ) ; // call converter to int only once
2020-11-06 16:09:13 +00:00
// AddLog_P(LOG_LEVEL_DEBUG_MORE, PSTR(D_LOG_ZIGBEE "Mapping type=%d offset=%d zigbee_type=%02X value=%d\n"), (uint8_t) map_type, map_offset, zigbee_type, ival32);
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switch ( ccccaaaa ) {
case 0xEF000202 :
case 0xEF000203 : // need to convert Tuya temperatures from 1/10 to 1/00 °C
ival32 = ival32 * 10 ;
break ;
}
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switch ( zigbee_type ) {
case Zenum8 :
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case Zmap8 :
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case Zbool :
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case Zuint8 : * ( uint8_t * ) attr_address = uval32 ; break ;
case Zenum16 :
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case Zmap16 :
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case Zuint16 : * ( uint16_t * ) attr_address = uval32 ; break ;
case Zuint32 : * ( uint32_t * ) attr_address = uval32 ; break ;
case Zint8 : * ( int8_t * ) attr_address = ival32 ; break ;
case Zint16 : * ( int16_t * ) attr_address = ival32 ; break ;
case Zint32 : * ( int32_t * ) attr_address = ival32 ; break ;
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}
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if ( Z_Data_Set : : updateData ( data ) ) {
zigbee_devices . dirty ( ) ;
}
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}
uint16_t uval16 = attr . getUInt ( ) ; // call converter to uint only once
int16_t ival16 = attr . getInt ( ) ; // call converter to int only once
// update any internal structure
switch ( ccccaaaa ) {
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case 0x00000004 : device . setManufId ( attr . getStr ( ) ) ; break ;
case 0x00000005 : device . setModelId ( attr . getStr ( ) ) ; break ;
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case 0x00010021 : device . setBatteryPercent ( uval16 / 2 ) ; break ;
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case 0x00060000 :
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case 0x00068000 : device . setPower ( attr . getBool ( ) , src_ep ) ; break ;
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}
2019-09-29 14:38:26 +01:00
2020-10-11 15:31:33 +01:00
// now apply the multiplier to make it human readable
if ( found ) {
if ( 0 = = conv_multiplier ) { attr_list . removeAttribute ( & attr ) ; continue ; } // remove attribute if multiplier is zero
if ( 1 ! = conv_multiplier ) {
if ( conv_multiplier > 0 ) { fval = fval * conv_multiplier ; }
else { fval = fval / ( - conv_multiplier ) ; }
attr . setFloat ( fval ) ;
}
}
2020-09-05 13:44:31 +01:00
// Replace cluster/attribute with name
if ( found ) {
if ( 0x00 ! = pgm_read_byte ( conv_name ) ) { // if name is not null, replace it
attr . setKeyName ( conv_name , true ) ; // PMEM string so no need to copy
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}
}
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}
}
}
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// Internal search function
void Z_parseAttributeKey_inner ( class Z_attribute & attr , uint16_t preferred_cluster ) {
// scan attributes to find by name, and retrieve type
for ( uint32_t i = 0 ; i < ARRAY_SIZE ( Z_PostProcess ) ; i + + ) {
const Z_AttributeConverter * converter = & Z_PostProcess [ i ] ;
uint16_t local_attr_id = pgm_read_word ( & converter - > attribute ) ;
uint16_t local_cluster_id = CxToCluster ( pgm_read_byte ( & converter - > cluster_short ) ) ;
uint8_t local_type_id = pgm_read_byte ( & converter - > type ) ;
int8_t local_multiplier = CmToMultiplier ( pgm_read_byte ( & converter - > multiplier_idx ) ) ;
// AddLog_P(LOG_LEVEL_DEBUG, PSTR("Try cluster = 0x%04X, attr = 0x%04X, type_id = 0x%02X"), local_cluster_id, local_attr_id, local_type_id);
if ( ! attr . key_is_str ) {
if ( ( attr . key . id . cluster = = local_cluster_id ) & & ( attr . key . id . attr_id = = local_attr_id ) ) {
attr . attr_type = local_type_id ;
break ;
}
} else if ( pgm_read_word ( & converter - > name_offset ) ) {
const char * key = attr . key . key ;
// AddLog_P(LOG_LEVEL_DEBUG, PSTR("Comparing '%s' with '%s'"), attr_name, converter->name);
if ( 0 = = strcasecmp_P ( key , Z_strings + pgm_read_word ( & converter - > name_offset ) ) ) {
if ( ( preferred_cluster = = 0xFFFF ) | | // any cluster
( local_cluster_id = = preferred_cluster ) ) {
// match
attr . setKeyId ( local_cluster_id , local_attr_id ) ;
attr . attr_type = local_type_id ;
attr . attr_multiplier = local_multiplier ;
break ;
}
}
}
}
}
2020-09-14 21:06:19 +01:00
//
// Given an attribute string, retrieve all attribute details.
// Input: the attribute has a key name, either: <cluster>/<attr> or <cluster>/<attr>%<type> or "<attribute_name>"
// Ex: "0008/0000", "0008/0000%20", "Dimmer"
// Use:
// Z_attribute attr;
// attr.setKeyName("0008/0000%20")
// if (Z_parseAttributeKey(attr)) {
// // ok
// }
//
// Output:
// The `attr` attribute has the correct cluster, attr_id, attr_type, attr_multiplier
// Note: the attribute value is unchanged and unparsed
//
// Note: if the type is specified in the key, the multiplier is not applied, no conversion happens
2020-12-06 18:20:42 +00:00
bool Z_parseAttributeKey ( class Z_attribute & attr , uint16_t preferred_cluster ) {
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// check if the name has the format "XXXX/YYYY" where XXXX is the cluster, YYYY the attribute id
// alternative "XXXX/YYYY%ZZ" where ZZ is the type (for unregistered attributes)
if ( attr . key_is_str ) {
const char * key = attr . key . key ;
char * delimiter = strchr ( key , ' / ' ) ;
char * delimiter2 = strchr ( key , ' % ' ) ;
if ( delimiter ) {
uint16_t attr_id = 0xFFFF ;
uint16_t cluster_id = 0xFFFF ;
uint8_t type_id = Zunk ;
cluster_id = strtoul ( key , & delimiter , 16 ) ;
if ( ! delimiter2 ) {
attr_id = strtoul ( delimiter + 1 , nullptr , 16 ) ;
} else {
attr_id = strtoul ( delimiter + 1 , & delimiter2 , 16 ) ;
type_id = strtoul ( delimiter2 + 1 , nullptr , 16 ) ;
}
attr . setKeyId ( cluster_id , attr_id ) ;
attr . attr_type = type_id ;
}
}
2020-11-06 16:09:13 +00:00
// AddLog_P(LOG_LEVEL_DEBUG, PSTR("cluster_id = 0x%04X, attr_id = 0x%04X"), cluster_id, attr_id);
2020-09-14 21:06:19 +01:00
// do we already know the type, i.e. attribute and cluster are also known
2020-12-06 18:20:42 +00:00
if ( ( Zunk = = attr . attr_type ) & & ( preferred_cluster ! = 0xFFFF ) ) {
Z_parseAttributeKey_inner ( attr , preferred_cluster ) ; // try to find with the selected cluster
}
2020-09-14 21:06:19 +01:00
if ( Zunk = = attr . attr_type ) {
2020-12-06 18:20:42 +00:00
Z_parseAttributeKey_inner ( attr , 0xFFFF ) ; // try again with any cluster
2020-09-14 21:06:19 +01:00
}
return ( Zunk ! = attr . attr_type ) ? true : false ;
}
2020-10-09 18:10:36 +01:00
// generic toAttributes() based on declaration in the attribute array
// can be overloaded for specific objects
// Input:
// the Json object to add attributes to
// the type of object (necessary since the type system is unaware of the actual sub-type)
2020-11-13 12:32:45 +00:00
void Z_Data : : toAttributes ( Z_attribute_list & attr_list ) const {
Z_Data_Type type = getType ( ) ;
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// iterate through attributes to see which ones need to be exported
for ( uint32_t i = 0 ; i < ARRAY_SIZE ( Z_PostProcess ) ; i + + ) {
const Z_AttributeConverter * converter = & Z_PostProcess [ i ] ;
uint8_t conv_export = pgm_read_byte ( & converter - > multiplier_idx ) & Z_EXPORT_DATA ;
uint8_t conv_mapping = pgm_read_byte ( & converter - > mapping ) ;
2020-11-11 11:09:18 +00:00
int8_t multiplier = CmToMultiplier ( pgm_read_byte ( & converter - > multiplier_idx ) ) ;
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Z_Data_Type map_type = ( Z_Data_Type ) ( ( conv_mapping & 0xF0 ) > > 4 ) ;
uint8_t map_offset = ( conv_mapping & 0x0F ) ;
if ( ( conv_export ! = 0 ) & & ( map_type = = type ) ) {
// we need to export this attribute
const char * conv_name = Z_strings + pgm_read_word ( & converter - > name_offset ) ;
uint8_t zigbee_type = pgm_read_byte ( & converter - > type ) ; // zigbee type to select right size 8/16/32 bits
2020-11-11 11:09:18 +00:00
uint8_t * attr_address = ( ( uint8_t * ) this ) + sizeof ( Z_Data ) + map_offset ; // address of attribute in memory
2020-10-09 18:10:36 +01:00
int32_t data_size = 0 ;
int32_t ival32 ;
uint32_t uval32 ;
switch ( zigbee_type ) {
case Zenum8 :
2020-10-28 19:59:55 +00:00
case Zmap8 :
2020-11-11 11:09:18 +00:00
case Zbool :
2020-11-27 21:53:42 +00:00
case Zuint8 : uval32 = * ( uint8_t * ) attr_address ; if ( uval32 ! = 0x000000FF ) data_size = 8 ; break ;
2020-10-28 19:59:55 +00:00
case Zmap16 :
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case Zenum16 :
2020-11-27 21:53:42 +00:00
case Zuint16 : uval32 = * ( uint16_t * ) attr_address ; if ( uval32 ! = 0x0000FFFF ) data_size = 16 ; break ;
case Zuint32 : uval32 = * ( uint32_t * ) attr_address ; if ( uval32 ! = 0xFFFFFFFF ) data_size = 32 ; break ;
2020-12-08 18:21:32 +00:00
case Zint8 : ival32 = * ( int8_t * ) attr_address ; if ( ival32 ! = - 0x80 ) data_size = - 8 ; break ;
case Zint16 : ival32 = * ( int16_t * ) attr_address ; if ( ival32 ! = - 0x8000 ) data_size = - 16 ; break ;
2020-10-09 18:10:36 +01:00
case Zint32 : ival32 = * ( int32_t * ) attr_address ; if ( ival32 ! = - 0x80000000 ) data_size = - 32 ; break ;
}
if ( data_size ! = 0 ) {
Z_attribute & attr = attr_list . addAttribute ( conv_name ) ;
2020-11-27 21:53:42 +00:00
float fval ;
if ( data_size > 0 ) { fval = uval32 ; }
else { fval = ival32 ; }
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if ( ( 1 ! = multiplier ) & & ( 0 ! = multiplier ) ) {
if ( multiplier > 0 ) { fval = fval * multiplier ; }
else { fval = fval / ( - multiplier ) ; }
}
attr . setFloat ( fval ) ;
2020-10-09 18:10:36 +01:00
}
}
}
}
2021-01-17 17:51:22 +00:00
// Add both attributes RGB and RGBb based on the inputs
// r,g,b are expected to be 100% brightness
// brightness is expected 0..255
void Z_Data_Light : : toRGBAttributesRGBb ( Z_attribute_list & attr_list , uint8_t r , uint8_t g , uint8_t b , uint8_t brightness ) {
SBuffer rgb ( 3 ) ;
rgb . add8 ( r ) ;
rgb . add8 ( g ) ;
rgb . add8 ( b ) ;
attr_list . addAttribute ( PSTR ( " RGB " ) , true ) . setBuf ( rgb , 0 , 3 ) ;
// now blend with brightness
r = changeUIntScale ( r , 0 , 255 , 0 , brightness ) ;
g = changeUIntScale ( g , 0 , 255 , 0 , brightness ) ;
b = changeUIntScale ( b , 0 , 255 , 0 , brightness ) ;
rgb . set8 ( 0 , r ) ;
rgb . set8 ( 1 , g ) ;
rgb . set8 ( 2 , b ) ;
attr_list . addAttribute ( PSTR ( " RGBb " ) , true ) . setBuf ( rgb , 0 , 3 ) ;
}
// Convert from Hue/Sat + Brightness to RGB+RGBb
// sat: 0..255
// hue: 0..359
// brightness: 0..255
void Z_Data_Light : : toRGBAttributesHSB ( Z_attribute_list & attr_list , uint16_t hue , uint8_t sat , uint8_t brightness ) {
uint8_t r , g , b ;
HsToRgb ( hue , sat , & r , & g , & b ) ;
Z_Data_Light : : toRGBAttributesRGBb ( attr_list , r , g , b , brightness ) ;
}
// Convert X/Y to RGB and RGBb
// X: 0..65535
// Y: 0..65535
// brightness: 0..255
void Z_Data_Light : : toRGBAttributesXYB ( Z_attribute_list & attr_list , uint16_t x , uint16_t y , uint8_t brightness ) {
uint8_t r , g , b ;
XyToRgb ( x / 65535.0f , y / 65535.0f , & r , & g , & b ) ;
Z_Data_Light : : toRGBAttributesRGBb ( attr_list , r , g , b , brightness ) ;
}
void Z_Data_Light : : toRGBAttributes ( Z_attribute_list & attr_list ) const {
uint8_t brightness = 255 ;
if ( validDimmer ( ) ) {
brightness = changeUIntScale ( getDimmer ( ) , 0 , 254 , 0 , 255 ) ; // range is 0..255
}
if ( validHue ( ) & & validSat ( ) ) {
uint8_t sat = changeUIntScale ( getSat ( ) , 0 , 254 , 0 , 255 ) ;
Z_Data_Light : : toRGBAttributesHSB ( attr_list , getHue ( ) , sat , brightness ) ;
} else if ( validX ( ) & & validY ( ) ) {
Z_Data_Light : : toRGBAttributesXYB ( attr_list , getX ( ) , getY ( ) , brightness ) ;
}
}
2020-11-07 13:34:23 +00:00
//
// Check if this device needs Battery reporting
2021-01-09 13:56:10 +00:00
// This is useful for IKEA or Philips devices that tend to drain battery quickly when Battery reporting is set
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//
bool Z_BatteryReportingDeviceSpecific ( uint16_t shortaddr ) {
const Z_Device & device = zigbee_devices . findShortAddr ( shortaddr ) ;
if ( device . manufacturerId ) {
String manuf_c ( device . manufacturerId ) ;
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if ( ( manuf_c . startsWith ( F ( " IKEA " ) ) ) | | ( manuf_c . startsWith ( F ( " Philips " ) ) ) ) {
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return false ;
}
}
return true ;
}
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# endif // USE_ZIGBEE