Tasmota/tasmota/xdrv_23_zigbee_5_converters.ino

/*
  xdrv_23_zigbee_converters.ino - zigbee support for Tasmota

  Copyright (C) 2019  Theo Arends and Stephan Hadinger

  This program is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
  the Free Software Foundation, either version 3 of the License, or
  (at your option) any later version.

  This program is distributed in the hope that it will be useful,
  but WITHOUT ANY WARRANTY; without even the implied warranty of
  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  GNU General Public License for more details.

  You should have received a copy of the GNU General Public License
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
*/

#ifdef USE_ZIGBEE

/*********************************************************************************************\
 * ZCL
\*********************************************************************************************/

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;


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 = 0, uint16_t groupid = 0):
    _cmd_id(cmd_id), _manuf_code(manuf_code), _transact_seq(transact_seq),
    _payload(buf_len ? buf_len : 250),      // allocate the data frame from source or preallocate big enough
    _cluster_id(clusterid), _group_id(groupid)
    {
      _frame_control.d8 = frame_control;
      _payload.addBuffer(buf, buf_len);
    };


  void publishMQTTReceived(uint16_t groupid, uint16_t clusterid, Z_ShortAddress srcaddr,
                           uint8_t srcendpoint, uint8_t dstendpoint, uint8_t wasbroadcast,
                           uint8_t linkquality, uint8_t securityuse, uint8_t seqnumber,
                           uint32_t timestamp) {
#ifdef ZIGBEE_VERBOSE
    char hex_char[_payload.len()*2+2];
		ToHex_P((unsigned char*)_payload.getBuffer(), _payload.len(), hex_char, sizeof(hex_char));
    Response_P(PSTR("{\"" D_JSON_ZIGBEEZCL_RECEIVED "\":{"
                    "\"groupid\":%d," "\"clusterid\":%d," "\"srcaddr\":\"0x%04X\","
                    "\"srcendpoint\":%d," "\"dstendpoint\":%d," "\"wasbroadcast\":%d,"
                    "\"" D_CMND_ZIGBEE_LINKQUALITY "\":%d," "\"securityuse\":%d," "\"seqnumber\":%d,"
                    "\"timestamp\":%d,"
                    "\"fc\":\"0x%02X\",\"manuf\":\"0x%04X\",\"transact\":%d,"
                    "\"cmdid\":\"0x%02X\",\"payload\":\"%s\""),
                    groupid, clusterid, srcaddr,
                    srcendpoint, dstendpoint, wasbroadcast,
                    linkquality, securityuse, seqnumber,
                    timestamp,
                    _frame_control, _manuf_code, _transact_seq, _cmd_id,
                    hex_char);

    ResponseJsonEnd();      // append '}'
    ResponseJsonEnd();      // append '}'
  	MqttPublishPrefixTopic_P(RESULT_OR_TELE, PSTR(D_JSON_ZIGBEEZCL_RECEIVED));
  	XdrvRulesProcess();
#endif
  }

  static ZCLFrame parseRawFrame(const SBuffer &buf, uint8_t offset, uint8_t len, uint16_t clusterid, uint16_t groupid) { // parse a raw frame and build the ZCL frame object
    uint32_t i = offset;
    ZCLHeaderFrameControl_t frame_control;
    uint16_t manuf_code = 0;
    uint8_t transact_seq;
    uint8_t cmd_id;

    frame_control.d8 = buf.get8(i++);
    if (frame_control.b.manuf_specific) {
      manuf_code = buf.get16(i);
      i += 2;
    }
    transact_seq = buf.get8(i++);
    cmd_id = buf.get8(i++);
    ZCLFrame zcl_frame(frame_control.d8, manuf_code, transact_seq, cmd_id,
                       (const char *)(buf.buf() + i), len + offset - i,
                       clusterid, groupid);
    return zcl_frame;
  }

  bool isClusterSpecificCommand(void) {
    return _frame_control.b.frame_type & 1;
  }

  void parseRawAttributes(JsonObject& json, uint8_t offset = 0);
  void parseReadAttributes(JsonObject& json, uint8_t offset = 0);
  void parseClusterSpecificCommand(JsonObject& json, uint8_t offset = 0);
  void postProcessAttributes(uint16_t shortaddr, JsonObject& json);

  inline void setGroupId(uint16_t groupid) {
    _group_id = groupid;
  }

  inline void setClusterId(uint16_t clusterid) {
    _cluster_id = clusterid;
  }

  inline uint8_t getCmdId(void) const {
    return _cmd_id;
  }

  inline uint16_t getClusterId(void) const {
    return _cluster_id;
  }

  const SBuffer &getPayload(void) const {
    return _payload;
  }

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;
  uint16_t                _cluster_id = 0;
  uint16_t                _group_id = 0;
  SBuffer                 _payload;
};

// 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;
}


uint32_t parseSingleAttribute(JsonObject& json, char *attrid_str, class SBuffer &buf,
                              uint32_t offset, uint32_t len) {

  uint32_t i = offset;
  uint32_t attrtype = buf.get8(i++);

  // fallback - enter a null value
  json[attrid_str] = (char*) nullptr;

  // now parse accordingly to attr type
  switch (attrtype) {
    case 0x00:      // nodata
    case 0xFF:      // unk
      break;
    case 0x10:      // bool
      {
        uint8_t val_bool = buf.get8(i++);
        if (0xFF != val_bool) {
          json[attrid_str] = (bool) (val_bool ? true : false);
        }
      }
      break;
    case 0x20:      // uint8
      {
        uint8_t uint8_val = buf.get8(i);
        i += 1;
        if (0xFF != uint8_val) {
          json[attrid_str] = uint8_val;
        }
      }
      break;
    case 0x21:      // uint16
      {
        uint16_t uint16_val = buf.get16(i);
        i += 2;
        if (0xFFFF != uint16_val) {
          json[attrid_str] = uint16_val;
        }
      }
      break;
    case 0x23:      // uint32
      {
        uint32_t uint32_val = buf.get32(i);
        i += 4;
        if (0xFFFFFFFF != uint32_val) {
          json[attrid_str] = uint32_val;
        }
      }
      break;
    // Note: uint40, uint48, uint56, uint64 are stored as Hex
    case 0x24:    // uint40
    case 0x25:    // uint48
    case 0x26:    // uint56
    case 0x27:    // uint64
      {
        uint8_t len = attrtype - 0x1F;   // 5 - 8
        // print as HEX
        char hex[2*len+1];
        ToHex_P(buf.buf(i), len, hex, sizeof(hex));
        json[attrid_str] = hex;
        i += len;
      }
      break;
    case 0x28:      // uint8
      {
        int8_t int8_val = buf.get8(i);
        i += 1;
        if (0x80 != int8_val) {
          json[attrid_str] = int8_val;
        }
      }
      break;
    case 0x29:      // uint16
      {
        int16_t int16_val = buf.get16(i);
        i += 2;
        if (0x8000 != int16_val) {
          json[attrid_str] = int16_val;
        }
      }
      break;
    case 0x2B:      // uint16
      {
        int32_t int32_val = buf.get32(i);
        i += 4;
        if (0x80000000 != int32_val) {
          json[attrid_str] = int32_val;
        }
      }
      break;
    // Note: int40, int48, int56, int64 are not stored as Hex
    case 0x2C:    // int40
    case 0x2D:    // int48
    case 0x2E:    // int56
    case 0x2F:    // int64
      {
        uint8_t len = attrtype - 0x27;   // 5 - 8
        // print as HEX
        char hex[2*len+1];
        ToHex_P(buf.buf(i), len, hex, sizeof(hex));
        json[attrid_str] = hex;
        i += len;
      }
      break;

    case 0x41:      // octet string, 1 byte len
    case 0x42:      // char string, 1 byte len
    case 0x43:      // octet string, 2 bytes len
    case 0x44:      // 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;
        uint32_t len = (attrtype <= 0x42) ? buf.get8(i) : buf.get16(i);    // len is 8 or 16 bits
        i += (attrtype <= 0x42) ? 1 : 2;                                   // increment pointer

        // check if we can safely use a string
        if ((0x41 == attrtype) || (0x43 == attrtype)) { parse_as_string = false; }
        else {
          for (uint32_t j = 0; j < len; j++) {
            if (0x00 == buf.get8(i+j)) {
              parse_as_string = false;
              break;
            }
          }
        }

        if (parse_as_string) {
          char str[len+1];
          strncpy(str, buf.charptr(i), len);
          str[len] = 0x00;
          json[attrid_str] = str;
        } else {
          // print as HEX
          char hex[2*len+1];
          ToHex_P(buf.buf(i), len, hex, sizeof(hex));
          json[attrid_str] = hex;
        }

        i += len;
        break;
      }
      i += buf.get8(i) + 1;
      break;

    case 0x08:      // data8
    case 0x18:      // map8
      {
        uint8_t uint8_val = buf.get8(i);
        i += 1;
        json[attrid_str] = uint8_val;
      }
      break;
    case 0x09:      // data16
    case 0x19:      // map16
      {
        uint16_t uint16_val = buf.get16(i);
        i += 2;
        json[attrid_str] = uint16_val;
      }
      break;
    case 0x0B:      // data32
    case 0x1B:      // map32
      {
        uint32_t uint32_val = buf.get32(i);
        i += 4;
        json[attrid_str] = uint32_val;
      }
      break;
    // enum
    case 0x30:      // enum8
    case 0x31:      // enum16
      i += attrtype - 0x2F;
      break;

    // TODO
    case 0x39:      // float
      i += 4;
      break;

    case 0xE0:      // ToD
    case 0xE1:      // date
    case 0xE2:      // UTC
      i += 4;
      break;

    case 0xE8:      // clusterId
    case 0xE9:      // attribId
      i += 2;
      break;
    case 0xEA:      // bacOID
      i += 4;
      break;

    case 0xF0:      // EUI64
      i += 8;
      break;
    case 0xF1:      // key128
      i += 16;
      break;

    // Other un-implemented data types
    case 0x0A:      // data24
    case 0x0C:      // data40
    case 0x0D:      // data48
    case 0x0E:      // data56
    case 0x0F:      // data64
      i += attrtype - 0x07;   // 2-8
      break;
    // map<x>
    case 0x1A:      // map24
    case 0x1C:      // map40
    case 0x1D:      // map48
    case 0x1E:      // map56
    case 0x1F:      // map64
      i += attrtype - 0x17;
      break;
    // semi
    case 0x38:      // semi (float on 2 bytes)
      i += 2;
      break;
    case 0x3A:      // double precision
      i += 8;
      break;
  }

  // String pp;    // pretty print
  // json[attrid_str].prettyPrintTo(pp);
  // // now store the attribute
  // AddLog_P2(LOG_LEVEL_INFO, PSTR("ZIG: ZCL attribute decoded, id %s, type 0x%02X, val=%s"),
  //                                attrid_str, attrtype, pp.c_str());
  return i - offset;    // how much have we increased the index
}


// First pass, parse all attributes in their native format
void ZCLFrame::parseRawAttributes(JsonObject& json, uint8_t offset) {
  uint32_t i = offset;
  uint32_t len = _payload.len();

  while (len - i >= 3) {
    uint16_t attrid = _payload.get16(i);
    i += 2;

    char key[16];
    snprintf_P(key, sizeof(key), PSTR("%04X/%04X"),
                _cluster_id, attrid);

    // exception for Xiaomi lumi.weather - specific field to be treated as octet and not char
    if ((0x0000 == _cluster_id) && (0xFF01 == attrid)) {
      if (0x42 == _payload.get8(i)) {
        _payload.set8(i, 0x41);   // change type from 0x42 to 0x41
      }
    }
    i += parseSingleAttribute(json, key, _payload, i, len);
  }
}

// ZCL_READ_ATTRIBUTES_RESPONSE
void ZCLFrame::parseReadAttributes(JsonObject& json, uint8_t offset) {
  uint32_t i = offset;
  uint32_t len = _payload.len();

  while (len - i >= 4) {
    uint16_t attrid = _payload.get16(i);
    i += 2;
    uint8_t status = _payload.get8(i++);

    if (0 == status) {
      char key[16];
      snprintf_P(key, sizeof(key), PSTR("%04X/%04X"),
                  _cluster_id, attrid);

      i += parseSingleAttribute(json, key, _payload, i, len);
    }
  }
}


// Parse non-normalized attributes
// The key is "s_" followed by 16 bits clusterId, "_" followed by 8 bits command id
void ZCLFrame::parseClusterSpecificCommand(JsonObject& json, uint8_t offset) {
  uint32_t i = offset;
  uint32_t len = _payload.len();

  char attrid_str[12];
  snprintf_P(attrid_str, sizeof(attrid_str), PSTR("%04X!%02X"), _cmd_id, _cluster_id);

  char hex_char[_payload.len()*2+2];
  ToHex_P((unsigned char*)_payload.getBuffer(), _payload.len(), hex_char, sizeof(hex_char));

  json[attrid_str] = hex_char;
}

// return value:
// 0 = keep initial value
// 1 = remove initial value
typedef int32_t (*Z_AttrConverter)(uint16_t shortaddr, JsonObject& json, const char *name, JsonVariant& value, const __FlashStringHelper* new_name);
typedef struct Z_AttributeConverter {
  uint16_t cluster;
  uint16_t attribute;
  const char * name;
  Z_AttrConverter func;
} Z_AttributeConverter;

// list of post-processing directives
const Z_AttributeConverter Z_PostProcess[] PROGMEM = {
  { 0x0000, 0x0000,  "ZCLVersion",           &Z_Copy },
  { 0x0000, 0x0001,  "AppVersion",           &Z_Copy },
  { 0x0000, 0x0002,  "StackVersion",         &Z_Copy },
  { 0x0000, 0x0003,  "HWVersion",            &Z_Copy },
  { 0x0000, 0x0004,  "Manufacturer",         &Z_ManufKeep },    // record Manufacturer
  { 0x0000, 0x0005,  D_JSON_MODEL D_JSON_ID, &Z_ModelKeep },    // record Model
  { 0x0000, 0x0006,  "DateCode",             &Z_Copy },
  { 0x0000, 0x0007,  "PowerSource",          &Z_Copy },
  { 0x0000, 0x4000,  "SWBuildID",            &Z_Copy },
  { 0x0000, 0xFFFF,  nullptr,                &Z_Remove },    // Remove all other values
  // Cmd 0x0A - Cluster 0x0000, attribute 0xFF01 - proprietary
  { 0x0000, 0xFF01,  nullptr,                &Z_AqaraSensor },    // Occupancy (map8)

  // Power Configuration cluster
  { 0x0001, 0x0000,  "MainsVoltage",         &Z_Copy },
  { 0x0001, 0x0001,  "MainsFrequency",       &Z_Copy },
  { 0x0001, 0x0020,  "BatteryVoltage",       &Z_Copy },
  { 0x0001, 0x0021,  "BatteryPercentageRemaining",&Z_Copy },

  // Device Temperature Configuration cluster
  { 0x0002, 0x0000,  "CurrentTemperature",   &Z_Copy },
  { 0x0002, 0x0001,  "MinTempExperienced",   &Z_Copy },
  { 0x0002, 0x0002,  "MaxTempExperienced",   &Z_Copy },
  { 0x0002, 0x0003,  "OverTempTotalDwell",   &Z_Copy },

  // On/off cluster
  { 0x0006, 0x0000,  "Power",                &Z_Copy },

  // On/Off Switch Configuration cluster
  { 0x0007, 0x0000,  "SwitchType",           &Z_Copy },

  // Level Control cluster
  { 0x0008, 0x0000,  "CurrentLevel",         &Z_Copy },
  // { 0x0008, 0x0001,  "RemainingTime",        &Z_Copy },
  // { 0x0008, 0x0010,  "OnOffTransitionTime",  &Z_Copy },
  // { 0x0008, 0x0011,  "OnLevel",              &Z_Copy },
  // { 0x0008, 0x0012,  "OnTransitionTime",     &Z_Copy },
  // { 0x0008, 0x0013,  "OffTransitionTime",    &Z_Copy },
  // { 0x0008, 0x0014,  "DefaultMoveRate",      &Z_Copy },
  
  // Alarms cluster
  { 0x0009, 0x0000,  "AlarmCount",           &Z_Copy },
  // Time cluster
  { 0x000A, 0x0000,  "Time",                 &Z_Copy },
  { 0x000A, 0x0001,  "TimeStatus",           &Z_Copy },
  { 0x000A, 0x0002,  "TimeZone",             &Z_Copy },
  { 0x000A, 0x0003,  "DstStart",             &Z_Copy },
  { 0x000A, 0x0004,  "DstStart",             &Z_Copy },
  { 0x000A, 0x0005,  "DstShift",             &Z_Copy },
  { 0x000A, 0x0006,  "StandardTime",         &Z_Copy },
  { 0x000A, 0x0007,  "LocalTime",            &Z_Copy },
  { 0x000A, 0x0008,  "LastSetTime",          &Z_Copy },
  { 0x000A, 0x0009,  "ValidUntilTime",       &Z_Copy },
  // RSSI Location cluster
  { 0x000B, 0x0000,  "LocationType",         &Z_Copy },
  { 0x000B, 0x0000,  "LocationMethod",       &Z_Copy },
  { 0x000B, 0x0000,  "LocationAge",          &Z_Copy },
  { 0x000B, 0x0000,  "QualityMeasure",       &Z_Copy },
  { 0x000B, 0x0000,  "NumberOfDevices",      &Z_Copy },
  // Analog Input cluster
  { 0x000C, 0x0004,  "ActiveText",           &Z_Copy },
  { 0x000C, 0x001C,  "Description",          &Z_Copy },
  { 0x000C, 0x002E,  "InactiveText",         &Z_Copy },
  { 0x000C, 0x0041,  "MaxPresentValue",      &Z_Copy },
  { 0x000C, 0x0045,  "MinPresentValue",      &Z_Copy },
  { 0x000C, 0x0051,  "OutOfService",         &Z_Copy },
  { 0x000C, 0x0055,  "PresentValue",         &Z_Copy },
  { 0x000C, 0x0057,  "PriorityArray",        &Z_Copy },
  { 0x000C, 0x0067,  "Reliability",          &Z_Copy },
  { 0x000C, 0x0068,  "RelinquishDefault",    &Z_Copy },
  { 0x000C, 0x006A,  "Resolution",           &Z_Copy },
  { 0x000C, 0x006F,  "StatusFlags",          &Z_Copy },
  { 0x000C, 0x0075,  "EngineeringUnits",     &Z_Copy },
  { 0x000C, 0x0100,  "ApplicationType",      &Z_Copy },
  // Binary Output cluster
  { 0x0010, 0x0004,  "ActiveText",           &Z_Copy },
  { 0x0010, 0x001C,  "Description",          &Z_Copy },
  { 0x0010, 0x002E,  "InactiveText",         &Z_Copy },
  { 0x0010, 0x0042,  "MinimumOffTime",       &Z_Copy },
  { 0x0010, 0x0043,  "MinimumOnTime",        &Z_Copy },
  { 0x0010, 0x0051,  "OutOfService",         &Z_Copy },
  { 0x0010, 0x0054,  "Polarity",             &Z_Copy },
  { 0x0010, 0x0055,  "PresentValue",         &Z_Copy },
  { 0x0010, 0x0057,  "PriorityArray",        &Z_Copy },
  { 0x0010, 0x0067,  "Reliability",          &Z_Copy },
  { 0x0010, 0x0068,  "RelinquishDefault",    &Z_Copy },
  { 0x0010, 0x006F,  "StatusFlags",          &Z_Copy },
  { 0x0010, 0x0100,  "ApplicationType",      &Z_Copy },
  // Binary Value cluster
  { 0x0011, 0x0004,  "ActiveText",           &Z_Copy },
  { 0x0011, 0x001C,  "Description",          &Z_Copy },
  { 0x0011, 0x002E,  "InactiveText",         &Z_Copy },
  { 0x0011, 0x0042,  "MinimumOffTime",       &Z_Copy },
  { 0x0011, 0x0043,  "MinimumOnTime",        &Z_Copy },
  { 0x0011, 0x0051,  "OutOfService",         &Z_Copy },
  { 0x0011, 0x0055,  "PresentValue",         &Z_Copy },
  { 0x0011, 0x0057,  "PriorityArray",        &Z_Copy },
  { 0x0011, 0x0067,  "Reliability",          &Z_Copy },
  { 0x0011, 0x0068,  "RelinquishDefault",    &Z_Copy },
  { 0x0011, 0x006F,  "StatusFlags",          &Z_Copy },
  { 0x0011, 0x0100,  "ApplicationType",      &Z_Copy },
  // Multistate Input cluster
  { 0x0012, 0x000E,  "StateText",            &Z_Copy },
  { 0x0012, 0x001C,  "Description",          &Z_Copy },
  { 0x0012, 0x004A,  "NumberOfStates",       &Z_Copy },
  { 0x0012, 0x0051,  "OutOfService",         &Z_Copy },
  { 0x0012, 0x0055,  "PresentValue",         &Z_Copy },
  { 0x0012, 0x0067,  "Reliability",          &Z_Copy },
  { 0x0012, 0x006F,  "StatusFlags",          &Z_Copy },
  { 0x0012, 0x0100,  "ApplicationType",      &Z_Copy },
  // Multistate output
  { 0x0013, 0x000E,  "StateText",            &Z_Copy },
  { 0x0013, 0x001C,  "Description",          &Z_Copy },
  { 0x0013, 0x004A,  "NumberOfStates",       &Z_Copy },
  { 0x0013, 0x0051,  "OutOfService",         &Z_Copy },
  { 0x0013, 0x0055,  "PresentValue",         &Z_Copy },
  { 0x0013, 0x0057,  "PriorityArray",        &Z_Copy },
  { 0x0013, 0x0067,  "Reliability",          &Z_Copy },
  { 0x0013, 0x0068,  "RelinquishDefault",    &Z_Copy },
  { 0x0013, 0x006F,  "StatusFlags",          &Z_Copy },
  { 0x0013, 0x0100,  "ApplicationType",      &Z_Copy },
  // Multistate Value cluster
  { 0x0014, 0x000E,  "StateText",            &Z_Copy },
  { 0x0014, 0x001C,  "Description",          &Z_Copy },
  { 0x0014, 0x004A,  "NumberOfStates",       &Z_Copy },
  { 0x0014, 0x0051,  "OutOfService",         &Z_Copy },
  { 0x0014, 0x0055,  "PresentValue",         &Z_Copy },
  { 0x0014, 0x0067,  "Reliability",          &Z_Copy },
  { 0x0014, 0x0068,  "RelinquishDefault",    &Z_Copy },
  { 0x0014, 0x006F,  "StatusFlags",          &Z_Copy },
  { 0x0014, 0x0100,  "ApplicationType",      &Z_Copy },
  // Power Profile cluster
  { 0x001A, 0x0000,  "TotalProfileNum",      &Z_Copy },
  { 0x001A, 0x0001,  "MultipleScheduling",   &Z_Copy },
  { 0x001A, 0x0002,  "EnergyFormatting",     &Z_Copy },
  { 0x001A, 0x0003,  "EnergyRemote",         &Z_Copy },
  { 0x001A, 0x0004,  "ScheduleMode",         &Z_Copy },
  // Poll Control cluster
  { 0x0020, 0x0000,  "CheckinInterval",      &Z_Copy },
  { 0x0020, 0x0001,  "LongPollInterval",     &Z_Copy },
  { 0x0020, 0x0002,  "ShortPollInterval",    &Z_Copy },
  { 0x0020, 0x0003,  "FastPollTimeout",      &Z_Copy },
  { 0x0020, 0x0004,  "CheckinIntervalMin",   &Z_Copy },
  { 0x0020, 0x0005,  "LongPollIntervalMin",  &Z_Copy },
  { 0x0020, 0x0006,  "FastPollTimeoutMax",   &Z_Copy },
  // Shade Configuration cluster
  { 0x0100, 0x0000,  "PhysicalClosedLimit",  &Z_Copy },
  { 0x0100, 0x0001,  "MotorStepSize",        &Z_Copy },
  { 0x0100, 0x0002,  "Status",               &Z_Copy },
  { 0x0100, 0x0010,  "ClosedLimit",          &Z_Copy },
  { 0x0100, 0x0011,  "Mode",                 &Z_Copy },
  // Door Lock cluster
  { 0x0101, 0x0000,  "LockState",            &Z_Copy },
  { 0x0101, 0x0001,  "LockType",             &Z_Copy },
  { 0x0101, 0x0002,  "ActuatorEnabled",      &Z_Copy },
  { 0x0101, 0x0003,  "DoorState",            &Z_Copy },
  { 0x0101, 0x0004,  "DoorOpenEvents",       &Z_Copy },
  { 0x0101, 0x0005,  "DoorClosedEvents",     &Z_Copy },
  { 0x0101, 0x0006,  "OpenPeriod",           &Z_Copy },
  // Window Covering cluster
  { 0x0102, 0x0000,  "WindowCoveringType",   &Z_Copy },
  { 0x0102, 0x0001,  "PhysicalClosedLimitLift",&Z_Copy },
  { 0x0102, 0x0002,  "PhysicalClosedLimitTilt",&Z_Copy },
  { 0x0102, 0x0003,  "CurrentPositionLift",  &Z_Copy },
  { 0x0102, 0x0004,  "CurrentPositionTilt",  &Z_Copy },
  { 0x0102, 0x0005,  "NumberofActuationsLift",&Z_Copy },
  { 0x0102, 0x0006,  "NumberofActuationsTilt",&Z_Copy },
  { 0x0102, 0x0007,  "ConfigStatus",         &Z_Copy },
  { 0x0102, 0x0008,  "CurrentPositionLiftPercentage",&Z_Copy },
  { 0x0102, 0x0009,  "CurrentPositionTiltPercentage",&Z_Copy },
  { 0x0102, 0x0010,  "InstalledOpenLimitLift",&Z_Copy },
  { 0x0102, 0x0011,  "InstalledClosedLimitLift",&Z_Copy },
  { 0x0102, 0x0012,  "InstalledOpenLimitTilt",  &Z_Copy },
  { 0x0102, 0x0013,  "InstalledClosedLimitTilt",  &Z_Copy },
  { 0x0102, 0x0014,  "VelocityLift",&Z_Copy },
  { 0x0102, 0x0015,  "AccelerationTimeLift",&Z_Copy },
  { 0x0102, 0x0016,  "DecelerationTimeLift",         &Z_Copy },
  { 0x0102, 0x0017,  "Mode",&Z_Copy },
  { 0x0102, 0x0018,  "IntermediateSetpointsLift",&Z_Copy },
  { 0x0102, 0x0019,  "IntermediateSetpointsTilt",&Z_Copy },

  // Color Control cluster
  { 0x0300, 0x0000,  "CurrentHue",           &Z_Copy },
  { 0x0300, 0x0001,  "CurrentSaturation",    &Z_Copy },
  { 0x0300, 0x0002,  "RemainingTime",        &Z_Copy },
  { 0x0300, 0x0003,  "CurrentX",             &Z_Copy },
  { 0x0300, 0x0004,  "CurrentY",             &Z_Copy },
  { 0x0300, 0x0005,  "DriftCompensation",    &Z_Copy },
  { 0x0300, 0x0006,  "CompensationText",     &Z_Copy },
  { 0x0300, 0x0007,  "ColorTemperatureMireds",&Z_Copy },
  { 0x0300, 0x0008,  "ColorMode",            &Z_Copy },
  { 0x0300, 0x0010,  "NumberOfPrimaries",    &Z_Copy },
  { 0x0300, 0x0011,  "Primary1X",            &Z_Copy },
  { 0x0300, 0x0012,  "Primary1Y",            &Z_Copy },
  { 0x0300, 0x0013,  "Primary1Intensity",    &Z_Copy },
  { 0x0300, 0x0015,  "Primary2X",            &Z_Copy },
  { 0x0300, 0x0016,  "Primary2Y",            &Z_Copy },
  { 0x0300, 0x0017,  "Primary2Intensity",    &Z_Copy },
  { 0x0300, 0x0019,  "Primary3X",            &Z_Copy },
  { 0x0300, 0x001A,  "Primary3Y",            &Z_Copy },
  { 0x0300, 0x001B,  "Primary3Intensity",    &Z_Copy },
  { 0x0300, 0x0030,  "WhitePointX",          &Z_Copy },
  { 0x0300, 0x0031,  "WhitePointY",          &Z_Copy },
  { 0x0300, 0x0032,  "ColorPointRX",         &Z_Copy },
  { 0x0300, 0x0033,  "ColorPointRY",         &Z_Copy },
  { 0x0300, 0x0034,  "ColorPointRIntensity", &Z_Copy },
  { 0x0300, 0x0036,  "ColorPointGX",         &Z_Copy },
  { 0x0300, 0x0037,  "ColorPointGY",         &Z_Copy },
  { 0x0300, 0x0038,  "ColorPointGIntensity", &Z_Copy },
  { 0x0300, 0x003A,  "ColorPointBX",         &Z_Copy },
  { 0x0300, 0x003B,  "ColorPointBY",         &Z_Copy },
  { 0x0300, 0x003C,  "ColorPointBIntensity", &Z_Copy },

  // Illuminance Measurement cluster
  { 0x0400, 0x0000,  D_JSON_ILLUMINANCE,     &Z_Copy },    // Illuminance (in Lux)
  { 0x0400, 0x0001,  "MinMeasuredValue",     &Z_Copy },    //
  { 0x0400, 0x0002,  "MaxMeasuredValue",     &Z_Copy },    //
  { 0x0400, 0x0003,  "Tolerance",            &Z_Copy },    //
  { 0x0400, 0x0004,  "LightSensorType",      &Z_Copy },    //
  { 0x0400, 0xFFFF,  nullptr,                &Z_Remove },    // Remove all other values

  // Illuminance Level Sensing cluster
  { 0x0401, 0x0000,  "LevelStatus",          &Z_Copy },    // Illuminance (in Lux)
  { 0x0401, 0x0001,  "LightSensorType",      &Z_Copy },    // LightSensorType
  { 0x0401, 0xFFFF,  nullptr,                &Z_Remove },    // Remove all other values

  // Temperature Measurement cluster
  { 0x0402, 0x0000,  D_JSON_TEMPERATURE,     &Z_FloatDiv100 },   // Temperature
  { 0x0402, 0x0001,  "MinMeasuredValue",     &Z_FloatDiv100 },    //
  { 0x0402, 0x0002,  "MaxMeasuredValue",     &Z_FloatDiv100 },    //
  { 0x0402, 0x0003,  "Tolerance",            &Z_FloatDiv100 },    //
  { 0x0402, 0xFFFF,  nullptr,                &Z_Remove },     // Remove all other values

  // Pressure Measurement cluster
  { 0x0403, 0x0000,  D_JSON_PRESSURE_UNIT,   &Z_AddPressureUnit },     // Pressure Unit
  { 0x0403, 0x0000,  D_JSON_PRESSURE,        &Z_Copy },     // Pressure
  { 0x0403, 0x0001,  "MinMeasuredValue",     &Z_Copy },    //
  { 0x0403, 0x0002,  "MaxMeasuredValue",     &Z_Copy },    //
  { 0x0403, 0x0003,  "Tolerance",            &Z_Copy },    //
  { 0x0403, 0x0010,  "ScaledValue",          &Z_Copy },    //
  { 0x0403, 0x0011,  "MinScaledValue",       &Z_Copy },    //
  { 0x0403, 0x0012,  "MaxScaledValue",       &Z_Copy },    //
  { 0x0403, 0x0013,  "ScaledTolerance",      &Z_Copy },    //
  { 0x0403, 0x0014,  "Scale",                &Z_Copy },    //
  { 0x0403, 0xFFFF,  nullptr,                &Z_Remove },     // Remove all other Pressure values

  // Flow Measurement cluster
  { 0x0404, 0x0000,  D_JSON_FLOWRATE,        &Z_FloatDiv10 },    // Flow (in m3/h)
  { 0x0404, 0x0001,  "MinMeasuredValue",     &Z_Copy },    //
  { 0x0404, 0x0002,  "MaxMeasuredValue",     &Z_Copy },    //
  { 0x0404, 0x0003,  "Tolerance",            &Z_Copy },    //
  { 0x0404, 0xFFFF,  nullptr,                &Z_Remove },    // Remove all other values

  // Relative Humidity Measurement cluster
  { 0x0405, 0x0000,  D_JSON_HUMIDITY,        &Z_FloatDiv100 },   // Humidity
  { 0x0405, 0x0001,  "MinMeasuredValue",     &Z_Copy },    //
  { 0x0405, 0x0002,  "MaxMeasuredValue",     &Z_Copy },    //
  { 0x0405, 0x0003,  "Tolerance",            &Z_Copy },    //
  { 0x0405, 0xFFFF,  nullptr,                &Z_Remove },     // Remove all other values

  // Occupancy Sensing cluster
  { 0x0406, 0x0000,  "Occupancy",            &Z_Copy },    // Occupancy (map8)
  { 0x0406, 0x0001,  "OccupancySensorType",  &Z_Copy },    // OccupancySensorType
  { 0x0406, 0xFFFF,  nullptr,                &Z_Remove },    // Remove all other values

  // Meter Identification cluster
  { 0x0B01, 0x0000,  "CompanyName",          &Z_Copy },
  { 0x0B01, 0x0001,  "MeterTypeID",          &Z_Copy },
  { 0x0B01, 0x0004,  "DataQualityID",        &Z_Copy },
  { 0x0B01, 0x0005,  "CustomerName",         &Z_Copy },
  { 0x0B01, 0x0006,  "Model",                &Z_Copy },
  { 0x0B01, 0x0007,  "PartNumber",           &Z_Copy },
  { 0x0B01, 0x000A,  "SoftwareRevision",     &Z_Copy },
  { 0x0B01, 0x000C,  "POD",                  &Z_Copy },
  { 0x0B01, 0x000D,  "AvailablePower",       &Z_Copy },
  { 0x0B01, 0x000E,  "PowerThreshold",       &Z_Copy },

  // Diagnostics cluster
  { 0x0B05, 0x0000,  "NumberOfResets",       &Z_Copy },
  { 0x0B05, 0x0001,  "PersistentMemoryWrites",&Z_Copy },
  { 0x0B05, 0x011C,  "LastMessageLQI",       &Z_Copy },
  { 0x0B05, 0x011D,  "LastMessageRSSI",      &Z_Copy },

};

// ======================================================================
// Record Manuf
int32_t Z_ManufKeep(uint16_t shortaddr, JsonObject& json, const char *name, JsonVariant& value, const __FlashStringHelper *new_name) {
  json[new_name] = value;
  zigbee_devices.setManufId(shortaddr, value.as<const char*>());
  return 1;
}
//
int32_t Z_ModelKeep(uint16_t shortaddr, JsonObject& json, const char *name, JsonVariant& value, const __FlashStringHelper *new_name) {
  json[new_name] = value;
  zigbee_devices.setModelId(shortaddr, value.as<const char*>());
  return 1;
}

// ======================================================================
// Remove attribute
int32_t Z_Remove(uint16_t shortaddr, JsonObject& json, const char *name, JsonVariant& value, const __FlashStringHelper *new_name) {
  return 1;   // remove original key
}

// Copy value as-is
int32_t Z_Copy(uint16_t shortaddr, JsonObject& json, const char *name, JsonVariant& value, const __FlashStringHelper *new_name) {
  json[new_name] = value;
  return 1;   // remove original key
}

// Add pressure unit
int32_t Z_AddPressureUnit(uint16_t shortaddr, JsonObject& json, const char *name, JsonVariant& value, const __FlashStringHelper *new_name) {
  json[new_name] = F(D_UNIT_PRESSURE);
  return 0;   // keep original key
}

// Convert int to float and divide by 100
int32_t Z_FloatDiv100(uint16_t shortaddr, JsonObject& json, const char *name, JsonVariant& value, const __FlashStringHelper *new_name) {
  json[new_name] = ((float)value) / 100.0f;
  return 1;   // remove original key
}
// Convert int to float and divide by 10
int32_t Z_FloatDiv10(uint16_t shortaddr, JsonObject& json, const char *name, JsonVariant& value, const __FlashStringHelper *new_name) {
  json[new_name] = ((float)value) / 10.0f;
  return 1;   // remove original key
}

int32_t Z_AqaraSensor(uint16_t shortaddr, JsonObject& json, const char *name, JsonVariant& value, const __FlashStringHelper *new_name) {
  String hex = value;
  SBuffer buf2 = SBuffer::SBufferFromHex(hex.c_str(), hex.length());
  uint32_t i = 0;
  uint32_t len = buf2.len();
  char tmp[] = "tmp";   // for obscure reasons, it must be converted from const char* to char*, otherwise ArduinoJson gets confused

  JsonVariant sub_value;

  while (len - i >= 2) {
    uint8_t attrid = buf2.get8(i++);

    i += parseSingleAttribute(json, tmp, buf2, i, len);
    float val = json[tmp];
    json.remove(tmp);
    if (0x64 == attrid) {
      json[F(D_JSON_TEMPERATURE)] = val / 100.0f;
    } else if (0x65 == attrid) {
      json[F(D_JSON_HUMIDITY)] = val / 100.0f;
    } else if (0x66 == attrid) {
      json[F(D_JSON_PRESSURE)] = val / 100.0f;
      json[F(D_JSON_PRESSURE_UNIT)] = F(D_UNIT_PRESSURE);   // hPa
    } else if (0x01 == attrid) {
      json[F(D_JSON_VOLTAGE)] = val / 1000.0f;
      json[F("Battery")] = toPercentageCR2032(val);
    }
  }
  return 1;   // remove original key
}
// ======================================================================

// Cluster Specific commands
// #define ZCL_OO_OFF          "s_0006_00"       // Cluster 0x0006, cmd 0x00 - On/Off - Off
// #define ZCL_OO_ON           "s_0006_01"       // Cluster 0x0006, cmd 0x01 - On/Off - On
// #define ZCL_COLORTEMP_MOVE  "s_0300_0A"       // Cluster 0x0300, cmd 0x0A, Move to Color Temp
// #define ZCL_LC_MOVE         "s_0008_00"       // Cluster 0x0008, cmd 0x00, Level Control Move to Level
// #define ZCL_LC_MOVE_1       "s_0008_01"       // Cluster 0x0008, cmd 0x01, Level Control Move
// #define ZCL_LC_STEP         "s_0008_02"       // Cluster 0x0008, cmd 0x02, Level Control Step
// #define ZCL_LC_STOP         "s_0008_03"       // Cluster 0x0008, cmd 0x03, Level Control Stop
// #define ZCL_LC_MOVE_WOO     "s_0008_04"       // Cluster 0x0008, cmd 0x04, Level Control Move to Level, with On/Off
// #define ZCL_LC_MOVE_1_WOO   "s_0008_05"       // Cluster 0x0008, cmd 0x05, Level Control Move, with On/Off
// #define ZCL_LC_STEP_WOO     "s_0008_06"       // Cluster 0x0008, cmd 0x05, Level Control Step, with On/Off
// #define ZCL_LC_STOP_WOO     "s_0008_07"       // Cluster 0x0008, cmd 0x07, Level Control Stop


void ZCLFrame::postProcessAttributes(uint16_t shortaddr, JsonObject& json) {
  // iterate on json elements
  for (auto kv : json) {
    String key_string = kv.key;
    const char * key = key_string.c_str();
    JsonVariant& value = kv.value;
    // Check that format looks like "CCCC/AAAA"
    char * delimiter = strchr(key, '/');
    if (delimiter) {
      uint16_t cluster = strtoul(key, &delimiter, 16);
      uint16_t attribute = strtoul(delimiter+1, nullptr, 16);

      // Iterate on filter
      for (uint32_t i = 0; i < sizeof(Z_PostProcess) / sizeof(Z_PostProcess[0]); i++) {
        const Z_AttributeConverter *converter = &Z_PostProcess[i];
        uint16_t conv_cluster = pgm_read_word(&converter->cluster);
        uint16_t conv_attribute = pgm_read_word(&converter->attribute);

        if ((conv_cluster == cluster) &&
            ((conv_attribute == attribute) || (conv_attribute == 0xFFFF)) ) {
          int32_t drop = (*converter->func)(shortaddr, json, key, value, (const __FlashStringHelper*) converter->name);
          if (drop) {
            json.remove(key);
          }

        }
      }
    }
  }
}

//void ZCLFrame::postProcessAttributes2(JsonObject& json) {
// void postProcessAttributes2(JsonObject& json) {
//   const __FlashStringHelper *key;
//
//   // Osram Mini Switch
//   key = F(ZCL_OO_OFF);
//   if (json.containsKey(key)) {
//     json.remove(key);
//     json[F(D_CMND_POWER)] = F("Off");
//   }
//   key = F(ZCL_OO_ON);
//   if (json.containsKey(key)) {
//     json.remove(key);
//     json[F(D_CMND_POWER)] = F("On");
//   }
//   key = F(ZCL_COLORTEMP_MOVE);
//   if (json.containsKey(key)) {
//     String hex = json[key];
//     SBuffer buf2 = SBuffer::SBufferFromHex(hex.c_str(), hex.length());
//     uint16_t color_temp = buf2.get16(0);
//     uint16_t transition_time = buf2.get16(2);
//     json.remove(key);
//     json[F("ColorTemp")] = color_temp;
//     json[F("TransitionTime")] = transition_time / 10.0f;
//   }
//   key = F(ZCL_LC_MOVE_WOO);
//   if (json.containsKey(key)) {
//     String hex = json[key];
//     SBuffer buf2 = SBuffer::SBufferFromHex(hex.c_str(), hex.length());
//     uint8_t level = buf2.get8(0);
//     uint16_t transition_time = buf2.get16(1);
//     json.remove(key);
//     json[F("Dimmer")] = changeUIntScale(level, 0, 255, 0, 100);  // change to percentage
//     json[F("TransitionTime")] = transition_time / 10.0f;
//     if (0 == level) {
//       json[F(D_CMND_POWER)] = F("Off");
//     } else {
//       json[F(D_CMND_POWER)] = F("On");
//     }
//   }
//   key = F(ZCL_LC_MOVE);
//   if (json.containsKey(key)) {
//     String hex = json[key];
//     SBuffer buf2 = SBuffer::SBufferFromHex(hex.c_str(), hex.length());
//     uint8_t level = buf2.get8(0);
//     uint16_t transition_time = buf2.get16(1);
//     json.remove(key);
//     json[F("Dimmer")] = changeUIntScale(level, 0, 255, 0, 100);  // change to percentage
//     json[F("TransitionTime")] = transition_time / 10.0f;
//   }
//   key = F(ZCL_LC_MOVE_1);
//   if (json.containsKey(key)) {
//     String hex = json[key];
//     SBuffer buf2 = SBuffer::SBufferFromHex(hex.c_str(), hex.length());
//     uint8_t move_mode = buf2.get8(0);
//     uint8_t move_rate = buf2.get8(1);
//     json.remove(key);
//     json[F("Move")] = move_mode ? F("Down") : F("Up");
//     json[F("Rate")] = move_rate;
//   }
//   key = F(ZCL_LC_MOVE_1_WOO);
//   if (json.containsKey(key)) {
//     String hex = json[key];
//     SBuffer buf2 = SBuffer::SBufferFromHex(hex.c_str(), hex.length());
//     uint8_t move_mode = buf2.get8(0);
//     uint8_t move_rate = buf2.get8(1);
//     json.remove(key);
//     json[F("Move")] = move_mode ? F("Down") : F("Up");
//     json[F("Rate")] = move_rate;
//     if (0 == move_mode) {
//       json[F(D_CMND_POWER)] = F("On");
//     }
//   }
//   key = F(ZCL_LC_STEP);
//   if (json.containsKey(key)) {
//     String hex = json[key];
//     SBuffer buf2 = SBuffer::SBufferFromHex(hex.c_str(), hex.length());
//     uint8_t step_mode = buf2.get8(0);
//     uint8_t step_size = buf2.get8(1);
//     uint16_t transition_time = buf2.get16(2);
//     json.remove(key);
//     json[F("Step")] = step_mode ? F("Down") : F("Up");
//     json[F("StepSize")] = step_size;
//     json[F("TransitionTime")] = transition_time / 10.0f;
//   }
//   key = F(ZCL_LC_STEP_WOO);
//   if (json.containsKey(key)) {
//     String hex = json[key];
//     SBuffer buf2 = SBuffer::SBufferFromHex(hex.c_str(), hex.length());
//     uint8_t step_mode = buf2.get8(0);
//     uint8_t step_size = buf2.get8(1);
//     uint16_t transition_time = buf2.get16(2);
//     json.remove(key);
//     json[F("Step")] = step_mode ? F("Down") : F("Up");
//     json[F("StepSize")] = step_size;
//     json[F("TransitionTime")] = transition_time / 10.0f;
//     if (0 == step_mode) {
//       json[F(D_CMND_POWER)] = F("On");
//     }
//   }
//   key = F(ZCL_LC_STOP);
//   if (json.containsKey(key)) {
//     json.remove(key);
//     json[F("Stop")] = 1;
//   }
//   key = F(ZCL_LC_STOP_WOO);
//   if (json.containsKey(key)) {
//     json.remove(key);
//     json[F("Stop")] = 1;
//   }
//
//   // Lumi.weather proprietary field
//   key = F(ZCL_LUMI_WEATHER);
//   if (json.containsKey(key)) {
//     String hex = json[key];
//     SBuffer buf2 = SBuffer::SBufferFromHex(hex.c_str(), hex.length());
//     DynamicJsonBuffer jsonBuffer;
//     JsonObject& json_lumi = jsonBuffer.createObject();
//     uint32_t i = 0;
//     uint32_t len = buf2.len();
//     char shortaddr[8];
//
//     while (len - i >= 2) {
//       uint8_t attrid = buf2.get8(i++);
//
//       snprintf_P(shortaddr, sizeof(shortaddr), PSTR("0x%02X"), attrid);
//
//       //json[shortaddr] = parseSingleAttribute(json_lumi, buf2, i, len, nullptr, 0);
//     }
//     // parse output
//     if (json_lumi.containsKey("0x64")) {    // Temperature
//       int32_t temperature = json_lumi["0x64"];
//       json[F(D_JSON_TEMPERATURE)] = temperature / 100.0f;
//     }
//     if (json_lumi.containsKey("0x65")) {    // Humidity
//       uint32_t humidity = json_lumi["0x65"];
//       json[F(D_JSON_HUMIDITY)] = humidity / 100.0f;
//     }
//     if (json_lumi.containsKey("0x66")) {    // Pressure
//       int32_t pressure = json_lumi["0x66"];
//       json[F(D_JSON_PRESSURE)] = pressure / 100.0f;
//       json[F(D_JSON_PRESSURE_UNIT)] = F(D_UNIT_PRESSURE);   // hPa
//     }
//     if (json_lumi.containsKey("0x01")) {    // Battery Voltage
//       uint32_t voltage = json_lumi["0x01"];
//       json[F(D_JSON_VOLTAGE)] = voltage / 1000.0f;
//       json[F("Battery")] = toPercentageCR2032(voltage);
//     }
//     json.remove(key);
//   }
//
// }

#endif // USE_ZIGBEE