/* xdrv_23_zigbee.ino - zigbee support for Tasmota Copyright (C) 2020 Theo Arends and Stephan Hadinger This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ #ifdef USE_ZIGBEE #define XDRV_23 23 const char kZbCommands[] PROGMEM = D_PRFX_ZB "|" // prefix #ifdef USE_ZIGBEE_ZNP D_CMND_ZIGBEEZNPSEND "|" D_CMND_ZIGBEEZNPRECEIVE "|" #endif // USE_ZIGBEE_ZNP #ifdef USE_ZIGBEE_EZSP D_CMND_ZIGBEE_EZSP_SEND "|" D_CMND_ZIGBEE_EZSP_RECEIVE "|" D_CMND_ZIGBEE_EZSP_LISTEN "|" #endif // USE_ZIGBEE_EZSP D_CMND_ZIGBEE_PERMITJOIN "|" D_CMND_ZIGBEE_STATUS "|" D_CMND_ZIGBEE_RESET "|" D_CMND_ZIGBEE_SEND "|" D_CMND_ZIGBEE_PROBE "|" D_CMND_ZIGBEE_FORGET "|" D_CMND_ZIGBEE_SAVE "|" D_CMND_ZIGBEE_NAME "|" D_CMND_ZIGBEE_BIND "|" D_CMND_ZIGBEE_UNBIND "|" D_CMND_ZIGBEE_PING "|" D_CMND_ZIGBEE_MODELID "|" D_CMND_ZIGBEE_LIGHT "|" D_CMND_ZIGBEE_RESTORE "|" D_CMND_ZIGBEE_BIND_STATE "|" D_CMND_ZIGBEE_CONFIG ; void (* const ZigbeeCommand[])(void) PROGMEM = { #ifdef USE_ZIGBEE_ZNP &CmndZbZNPSend, &CmndZbZNPReceive, #endif // USE_ZIGBEE_ZNP #ifdef USE_ZIGBEE_EZSP &CmndZbEZSPSend, &CmndZbEZSPReceive, &CmndZbEZSPListen, #endif // USE_ZIGBEE_EZSP &CmndZbPermitJoin, &CmndZbStatus, &CmndZbReset, &CmndZbSend, &CmndZbProbe, &CmndZbForget, &CmndZbSave, &CmndZbName, &CmndZbBind, &CmndZbUnbind, &CmndZbPing, &CmndZbModelId, &CmndZbLight, &CmndZbRestore, &CmndZbBindState, &CmndZbConfig, }; /********************************************************************************************/ // Initialize internal structures void ZigbeeInit(void) { // Check if settings in Flash are set if (PinUsed(GPIO_ZIGBEE_RX) && PinUsed(GPIO_ZIGBEE_TX)) { if (0 == Settings.zb_channel) { AddLog_P2(LOG_LEVEL_INFO, PSTR(D_LOG_ZIGBEE "Randomizing Zigbee parameters, please check with 'ZbConfig'")); uint64_t mac64 = 0; // stuff mac address into 64 bits WiFi.macAddress((uint8_t*) &mac64); uint32_t esp_id = ESP_getChipId(); #ifdef ESP8266 uint32_t flash_id = ESP.getFlashChipId(); #else // ESP32 uint32_t flash_id = 0; #endif // ESP8266 or ESP32 uint16_t pan_id = (mac64 & 0x3FFF); if (0x0000 == pan_id) { pan_id = 0x0001; } // avoid extreme values if (0x3FFF == pan_id) { pan_id = 0x3FFE; } // avoid extreme values Settings.zb_pan_id = pan_id; Settings.zb_ext_panid = 0xCCCCCCCC00000000L | (mac64 & 0x00000000FFFFFFFFL); Settings.zb_precfgkey_l = (mac64 << 32) | (esp_id << 16) | flash_id; Settings.zb_precfgkey_h = (mac64 << 32) | (esp_id << 16) | flash_id; Settings.zb_channel = USE_ZIGBEE_CHANNEL; Settings.zb_txradio_dbm = USE_ZIGBEE_TXRADIO_DBM; } } // update commands with the current settings #ifdef USE_ZIGBEE_ZNP ZNP_UpdateConfig(Settings.zb_channel, Settings.zb_pan_id, Settings.zb_ext_panid, Settings.zb_precfgkey_l, Settings.zb_precfgkey_h); #endif #ifdef USE_ZIGBEE_EZSP EZ_UpdateConfig(Settings.zb_channel, Settings.zb_pan_id, Settings.zb_ext_panid, Settings.zb_precfgkey_l, Settings.zb_precfgkey_h, Settings.zb_txradio_dbm); #endif ZigbeeInitSerial(); } /*********************************************************************************************\ * Commands \*********************************************************************************************/ uint32_t strToUInt(const JsonVariant &val) { // if the string starts with 0x, it is considered Hex, otherwise it is an int if (val.is()) { return val.as(); } else { if (val.is()) { String sval = val.as(); return strtoull(sval.c_str(), nullptr, 0); } } return 0; // couldn't parse anything } #ifdef USE_ZIGBEE_ZNP // Do a factory reset of the CC2530 const unsigned char ZIGBEE_FACTORY_RESET[] PROGMEM = { Z_SREQ | Z_SAPI, SAPI_WRITE_CONFIGURATION, CONF_STARTUP_OPTION, 0x01 /* len */, 0x01 /* STARTOPT_CLEAR_CONFIG */}; //"2605030101"; // Z_SREQ | Z_SAPI, SAPI_WRITE_CONFIGURATION, CONF_STARTUP_OPTION, 0x01 len, 0x01 STARTOPT_CLEAR_CONFIG #endif // USE_ZIGBEE_ZNP void CmndZbReset(void) { if (ZigbeeSerial) { switch (XdrvMailbox.payload) { case 1: #ifdef USE_ZIGBEE_ZNP ZigbeeZNPSend(ZIGBEE_FACTORY_RESET, sizeof(ZIGBEE_FACTORY_RESET)); #endif // USE_ZIGBEE_ZNP eraseZigbeeDevices(); restart_flag = 2; ResponseCmndChar_P(PSTR(D_JSON_ZIGBEE_CC2530 " " D_JSON_RESET_AND_RESTARTING)); break; default: ResponseCmndChar_P(PSTR(D_JSON_ONE_TO_RESET)); } } } /********************************************************************************************/ // // High-level function // Send a command specified as an HEX string for the workload. // The target endpoint is computed if zero, i.e. sent to the first known endpoint of the device. // If cluster-specific, a timer may be set calling `zigbeeSetCommandTimer()`, for ex to coalesce attributes or Aqara presence sensor // // Inputs: // - shortaddr: 16-bits short address, or 0x0000 if group address // - groupaddr: 16-bits group address, or 0x0000 if unicast using shortaddr // - endpoint: 8-bits target endpoint (source is always 0x01), if 0x00, it will be guessed from ZbStatus information (basically the first endpoint of the device) // - clusterSpecific: boolean, is the message general cluster or cluster specific, used to create the FC byte of ZCL // - clusterIf: 16-bits cluster number // - param: pointer to HEX string for payload, should not be nullptr // Returns: None // void zigbeeZCLSendStr(uint16_t shortaddr, uint16_t groupaddr, uint8_t endpoint, bool clusterSpecific, uint16_t manuf, uint16_t cluster, uint8_t cmd, const char *param) { size_t size = param ? strlen(param) : 0; SBuffer buf((size+2)/2); // actual bytes buffer for data if (param) { while (*param) { uint8_t code = parseHex_P(¶m, 2); buf.add8(code); } } if ((0 == endpoint) && (BAD_SHORTADDR != shortaddr)) { // endpoint is not specified, let's try to find it from shortAddr, unless it's a group address endpoint = zigbee_devices.findFirstEndpoint(shortaddr); //AddLog_P2(LOG_LEVEL_DEBUG, PSTR("ZbSend: guessing endpoint 0x%02X"), endpoint); } AddLog_P2(LOG_LEVEL_DEBUG, PSTR("ZbSend: shortaddr 0x%04X, groupaddr 0x%04X, cluster 0x%04X, endpoint 0x%02X, cmd 0x%02X, data %s"), shortaddr, groupaddr, cluster, endpoint, cmd, param); if ((0 == endpoint) && (BAD_SHORTADDR != shortaddr)) { // endpoint null is ok for group address AddLog_P2(LOG_LEVEL_INFO, PSTR("ZbSend: unspecified endpoint")); return; } // everything is good, we can send the command ZigbeeZCLSend_Raw(shortaddr, groupaddr, cluster, endpoint, cmd, clusterSpecific, manuf, buf.getBuffer(), buf.len(), true, zigbee_devices.getNextSeqNumber(shortaddr)); // now set the timer, if any, to read back the state later if (clusterSpecific) { #ifndef USE_ZIGBEE_NO_READ_ATTRIBUTES // read back attribute value unless it is disabled zigbeeSetCommandTimer(shortaddr, groupaddr, cluster, endpoint); #endif } } // Special encoding for multiplier: // multiplier == 0: ignore // multiplier == 1: ignore // multiplier > 0: divide by the multiplier // multiplier < 0: multiply by the -multiplier (positive) void ZbApplyMultiplier(double &val_d, int8_t multiplier) { if ((0 != multiplier) && (1 != multiplier)) { if (multiplier > 0) { // inverse of decoding val_d = val_d / multiplier; } else { val_d = val_d * (-multiplier); } } } // Parse "Report", "Write", "Response" or "Condig" attribute // Operation is one of: ZCL_REPORT_ATTRIBUTES (0x0A), ZCL_WRITE_ATTRIBUTES (0x02) or ZCL_READ_ATTRIBUTES_RESPONSE (0x01) void ZbSendReportWrite(const JsonObject &val_pubwrite, uint16_t device, uint16_t groupaddr, uint16_t cluster, uint8_t endpoint, uint16_t manuf, uint32_t operation) { SBuffer buf(200); // buffer to store the binary output of attibutes if (nullptr == XdrvMailbox.command) { XdrvMailbox.command = (char*) ""; // prevent a crash when calling ReponseCmndChar and there was no previous command } // iterate on keys for (JsonObject::const_iterator it=val_pubwrite.begin(); it!=val_pubwrite.end(); ++it) { const char *key = it->key; const JsonVariant &value = it->value; uint16_t attr_id = 0xFFFF; uint16_t cluster_id = 0xFFFF; uint8_t type_id = Znodata; int8_t multiplier = 1; // multiplier to adjust the key value double val_d = 0; // I try to avoid `double` but this type capture both float and (u)int32_t without prevision loss const char* val_str = ""; // variant as string // 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) char * delimiter = strchr(key, '/'); char * delimiter2 = strchr(key, '%'); if (delimiter) { 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); } } // AddLog_P2(LOG_LEVEL_DEBUG, PSTR("cluster_id = 0x%04X, attr_id = 0x%04X"), cluster_id, attr_id); // do we already know the type, i.e. attribute and cluster are also known if (Znodata == type_id) { // 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]; bool match = false; 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 = pgm_read_byte(&converter->multiplier); // AddLog_P2(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 (delimiter) { if ((cluster_id == local_cluster_id) && (attr_id == local_attr_id)) { type_id = local_type_id; break; } } else if (pgm_read_word(&converter->name_offset)) { // AddLog_P2(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))) { // match cluster_id = local_cluster_id; attr_id = local_attr_id; type_id = local_type_id; multiplier = local_multiplier; break; } } } } // Buffer ready, do some sanity checks // AddLog_P2(LOG_LEVEL_DEBUG, PSTR("cluster_id = 0x%04X, attr_id = 0x%04X, type_id = 0x%02X"), cluster_id, attr_id, type_id); if ((0xFFFF == attr_id) || (0xFFFF == cluster_id)) { Response_P(PSTR("{\"%s\":\"%s'%s'\"}"), XdrvMailbox.command, PSTR("Unknown attribute "), key); return; } if (Znodata == type_id) { Response_P(PSTR("{\"%s\":\"%s'%s'\"}"), XdrvMailbox.command, PSTR("Unknown attribute type for attribute "), key); return; } if (0xFFFF == cluster) { cluster = cluster_id; // set the cluster for this packet } else if (cluster != cluster_id) { ResponseCmndChar_P(PSTR("No more than one cluster id per command")); return; } // //////////////////////////////////////////////////////////////////////////////// // Split encoding depending on message if (operation != ZCL_CONFIGURE_REPORTING) { // apply multiplier if needed val_d = value.as(); val_str = value.as(); ZbApplyMultiplier(val_d, multiplier); // push the value in the buffer buf.add16(attr_id); // prepend with attribute identifier if (operation == ZCL_READ_ATTRIBUTES_RESPONSE) { buf.add8(Z_SUCCESS); // status OK = 0x00 } buf.add8(type_id); // prepend with attribute type int32_t res = encodeSingleAttribute(buf, val_d, val_str, type_id); if (res < 0) { // remove the attribute type we just added // buf.setLen(buf.len() - (operation == ZCL_READ_ATTRIBUTES_RESPONSE ? 4 : 3)); Response_P(PSTR("{\"%s\":\"%s'%s' 0x%02X\"}"), XdrvMailbox.command, PSTR("Unsupported attribute type "), key, type_id); return; } } else { // //////////////////////////////////////////////////////////////////////////////// // ZCL_CONFIGURE_REPORTING if (!value.is()) { ResponseCmndChar_P(PSTR("Config requires JSON objects")); return; } JsonObject &attr_config = value.as(); bool attr_direction = false; const JsonVariant &val_attr_direction = GetCaseInsensitive(attr_config, PSTR("DirectionReceived")); if (nullptr != &val_attr_direction) { uint32_t dir = strToUInt(val_attr_direction); if (dir) { attr_direction = true; } } // read MinInterval and MaxInterval, default to 0xFFFF if not specified uint16_t attr_min_interval = 0xFFFF; uint16_t attr_max_interval = 0xFFFF; const JsonVariant &val_attr_min = GetCaseInsensitive(attr_config, PSTR("MinInterval")); if (nullptr != &val_attr_min) { attr_min_interval = strToUInt(val_attr_min); } const JsonVariant &val_attr_max = GetCaseInsensitive(attr_config, PSTR("MaxInterval")); if (nullptr != &val_attr_max) { attr_max_interval = strToUInt(val_attr_max); } // read ReportableChange const JsonVariant &val_attr_rc = GetCaseInsensitive(attr_config, PSTR("ReportableChange")); if (nullptr != &val_attr_rc) { val_d = val_attr_rc.as(); val_str = val_attr_rc.as(); ZbApplyMultiplier(val_d, multiplier); } // read TimeoutPeriod uint16_t attr_timeout = 0x0000; const JsonVariant &val_attr_timeout = GetCaseInsensitive(attr_config, PSTR("TimeoutPeriod")); if (nullptr != &val_attr_timeout) { attr_timeout = strToUInt(val_attr_timeout); } bool attr_discrete = Z_isDiscreteDataType(type_id); // all fields are gathered, output the butes into the buffer, ZCL 2.5.7.1 // common bytes buf.add8(attr_direction ? 0x01 : 0x00); buf.add16(attr_id); if (attr_direction) { buf.add16(attr_timeout); } else { buf.add8(type_id); buf.add16(attr_min_interval); buf.add16(attr_max_interval); if (!attr_discrete) { int32_t res = encodeSingleAttribute(buf, val_d, val_str, type_id); if (res < 0) { Response_P(PSTR("{\"%s\":\"%s'%s' 0x%02X\"}"), XdrvMailbox.command, PSTR("Unsupported attribute type "), key, type_id); return; } } } } } // did we have any attribute? if (0 == buf.len()) { ResponseCmndChar_P(PSTR("No attribute in list")); return; } // all good, send the packet ZigbeeZCLSend_Raw(device, groupaddr, cluster, endpoint, operation, false /* not cluster specific */, manuf, buf.getBuffer(), buf.len(), false /* noresponse */, zigbee_devices.getNextSeqNumber(device)); ResponseCmndDone(); } // Parse the "Send" attribute and send the command void ZbSendSend(const JsonVariant &val_cmd, uint16_t device, uint16_t groupaddr, uint16_t cluster, uint8_t endpoint, uint16_t manuf) { uint8_t cmd = 0; String cmd_str = ""; // the actual low-level command, either specified or computed const char *cmd_s; // pointer to payload string bool clusterSpecific = true; static char delim[] = ", "; // delimiters for parameters // probe the type of the argument // If JSON object, it's high level commands // If String, it's a low level command if (val_cmd.is()) { // we have a high-level command const JsonObject &cmd_obj = val_cmd.as(); int32_t cmd_size = cmd_obj.size(); if (cmd_size > 1) { Response_P(PSTR("Only 1 command allowed (%d)"), cmd_size); return; } else if (1 == cmd_size) { // We have exactly 1 command, parse it JsonObject::const_iterator it = cmd_obj.begin(); // just get the first key/value String key = it->key; const JsonVariant& value = it->value; uint32_t x = 0, y = 0, z = 0; uint16_t cmd_var; uint16_t local_cluster_id; const __FlashStringHelper* tasmota_cmd = zigbeeFindCommand(key.c_str(), &local_cluster_id, &cmd_var); if (tasmota_cmd) { cmd_str = tasmota_cmd; } else { Response_P(PSTR("Unrecognized zigbee command: %s"), key.c_str()); return; } // check cluster if (0xFFFF == cluster) { cluster = local_cluster_id; } else if (cluster != local_cluster_id) { ResponseCmndChar_P(PSTR("No more than one cluster id per command")); return; } // parse the JSON value, depending on its type fill in x,y,z if (value.is()) { x = value.as() ? 1 : 0; } else if (value.is()) { x = value.as(); } else { // if non-bool or non-int, trying char* const char *s_const = value.as(); if (s_const != nullptr) { char s[strlen(s_const)+1]; strcpy(s, s_const); if ((nullptr != s) && (0x00 != *s)) { // ignore any null or empty string, could represent 'null' json value char *sval = strtok(s, delim); if (sval) { x = ZigbeeAliasOrNumber(sval); sval = strtok(nullptr, delim); if (sval) { y = ZigbeeAliasOrNumber(sval); sval = strtok(nullptr, delim); if (sval) { z = ZigbeeAliasOrNumber(sval); } } } } } } //AddLog_P2(LOG_LEVEL_DEBUG, PSTR("ZbSend: command_template = %s"), cmd_str.c_str()); if (0xFF == cmd_var) { // if command number is a variable, replace it with x cmd = x; x = y; // and shift other variables y = z; } else { cmd = cmd_var; // or simply copy the cmd number } cmd_str = zigbeeCmdAddParams(cmd_str.c_str(), x, y, z); // fill in parameters //AddLog_P2(LOG_LEVEL_DEBUG, PSTR("ZbSend: command_final = %s"), cmd_str.c_str()); cmd_s = cmd_str.c_str(); } else { // we have zero command, pass through until last error for missing command } } else if (val_cmd.is()) { // low-level command cmd_str = val_cmd.as(); // Now parse the string to extract cluster, command, and payload // Parse 'cmd' in the form "AAAA_BB/CCCCCCCC" or "AAAA!BB/CCCCCCCC" // where AA is the cluster number, BBBB the command number, CCCC... the payload // First delimiter is '_' for a global command, or '!' for a cluster specific command const char * data = cmd_str.c_str(); uint16_t local_cluster_id = parseHex(&data, 4); // check cluster if (0xFFFF == cluster) { cluster = local_cluster_id; } else if (cluster != local_cluster_id) { ResponseCmndChar_P(PSTR("No more than one cluster id per command")); return; } // delimiter if (('_' == *data) || ('!' == *data)) { if ('_' == *data) { clusterSpecific = false; } data++; } else { ResponseCmndChar_P(PSTR("Wrong delimiter for payload")); return; } // parse cmd number cmd = parseHex(&data, 2); // move to end of payload // delimiter is optional if ('/' == *data) { data++; } // skip delimiter cmd_s = data; } else { // we have an unsupported command type, just ignore it and fallback to missing command } AddLog_P2(LOG_LEVEL_DEBUG, PSTR("ZigbeeZCLSend device: 0x%04X, group: 0x%04X, endpoint:%d, cluster:0x%04X, cmd:0x%02X, send:\"%s\""), device, groupaddr, endpoint, cluster, cmd, cmd_s); zigbeeZCLSendStr(device, groupaddr, endpoint, clusterSpecific, manuf, cluster, cmd, cmd_s); ResponseCmndDone(); } // Parse the "Send" attribute and send the command void ZbSendRead(const JsonVariant &val_attr, uint16_t device, uint16_t groupaddr, uint16_t cluster, uint8_t endpoint, uint16_t manuf, uint32_t operation) { // ZbSend {"Device":"0xF289","Cluster":0,"Endpoint":3,"Read":5} // ZbSend {"Device":"0xF289","Cluster":"0x0000","Endpoint":"0x0003","Read":"0x0005"} // ZbSend {"Device":"0xF289","Cluster":0,"Endpoint":3,"Read":[5,6,7,4]} // ZbSend {"Device":"0xF289","Endpoint":3,"Read":{"ModelId":true}} // ZbSend {"Device":"0xF289","Read":{"ModelId":true}} // ZbSend {"Device":"0xF289","ReadConig":{"Power":true}} // ZbSend {"Device":"0xF289","Cluster":6,"Endpoint":3,"ReadConfig":0} // params size_t attrs_len = 0; uint8_t* attrs = nullptr; // empty string is valid size_t attr_item_len = 2; // how many bytes per attribute, standard for "Read" size_t attr_item_offset = 0; // how many bytes do we offset to store attribute if (ZCL_READ_REPORTING_CONFIGURATION == operation) { attr_item_len = 3; attr_item_offset = 1; } uint16_t val = strToUInt(val_attr); if (val_attr.is()) { const JsonArray& attr_arr = val_attr.as(); attrs_len = attr_arr.size() * attr_item_len; attrs = (uint8_t*) calloc(attrs_len, 1); uint32_t i = 0; for (auto value : attr_arr) { uint16_t val = strToUInt(value); i += attr_item_offset; attrs[i++] = val & 0xFF; attrs[i++] = val >> 8; i += attr_item_len - 2 - attr_item_offset; // normally 0 } } else if (val_attr.is()) { const JsonObject& attr_obj = val_attr.as(); attrs_len = attr_obj.size() * attr_item_len; attrs = (uint8_t*) calloc(attrs_len, 1); uint32_t actual_attr_len = 0; // iterate on keys for (JsonObject::const_iterator it=attr_obj.begin(); it!=attr_obj.end(); ++it) { const char *key = it->key; const JsonVariant &value = it->value; // we don't need the value here, only keys are relevant bool found = false; // 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]; bool match = false; 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); if ((pgm_read_word(&converter->name_offset)) && (0 == strcasecmp_P(key, Z_strings + pgm_read_word(&converter->name_offset)))) { // match name // check if there is a conflict with cluster // TODO if (!value && attr_item_offset) { // If value is false (non-default) then set direction to 1 (for ReadConfig) attrs[actual_attr_len] = 0x01; } actual_attr_len += attr_item_offset; attrs[actual_attr_len++] = local_attr_id & 0xFF; attrs[actual_attr_len++] = local_attr_id >> 8; actual_attr_len += attr_item_len - 2 - attr_item_offset; // normally 0 found = true; // check cluster if (0xFFFF == cluster) { cluster = local_cluster_id; } else if (cluster != local_cluster_id) { ResponseCmndChar_P(PSTR("No more than one cluster id per command")); if (attrs) { free(attrs); } return; } break; // found, exit loop } } if (!found) { AddLog_P2(LOG_LEVEL_INFO, PSTR("ZIG: Unknown attribute name (ignored): %s"), key); } } attrs_len = actual_attr_len; } else { attrs_len = attr_item_len; attrs = (uint8_t*) calloc(attrs_len, 1); attrs[0 + attr_item_offset] = val & 0xFF; // little endian attrs[1 + attr_item_offset] = val >> 8; } if (attrs_len > 0) { ZigbeeZCLSend_Raw(device, groupaddr, cluster, endpoint, operation, false, manuf, attrs, attrs_len, true /* we do want a response */, zigbee_devices.getNextSeqNumber(device)); ResponseCmndDone(); } else { ResponseCmndChar_P(PSTR("Missing parameters")); } if (attrs) { free(attrs); } } // // Command `ZbSend` // // Examples: // ZbSend {"Device":"0x0000","Endpoint":1,"Write":{"0006/0000":0}} // ZbSend {"Device":"0x0000","Endpoint":1,"Write":{"Power":0}} // ZbSend {"Device":"0x0000","Endpoint":1,"Write":{"AqaraRotate":0}} // ZbSend {"Device":"0x0000","Endpoint":1,"Write":{"AqaraRotate":12.5}} // ZbSend {"Device":"0x0000","Endpoint":1,"Write":{"006/0000%39":12.5}} // ZbSend {"Device":"0x0000","Endpoint":1,"Write":{"AnalogInApplicationType":1000000}} // ZbSend {"Device":"0x0000","Endpoint":1,"Write":{"TimeZone":-1000000}} // ZbSend {"Device":"0x0000","Endpoint":1,"Write":{"Manufacturer":"Tasmota","ModelId":"Tasmota Z2T Router"}} void CmndZbSend(void) { // ZbSend { "device":"0x1234", "endpoint":"0x03", "send":{"Power":1} } // ZbSend { "device":"0x1234", "endpoint":"0x03", "send":{"Power":"3"} } // ZbSend { "device":"0x1234", "endpoint":"0x03", "send":{"Power":"0xFF"} } // ZbSend { "device":"0x1234", "endpoint":"0x03", "send":{"Power":null} } // ZbSend { "device":"0x1234", "endpoint":"0x03", "send":{"Power":false} } // ZbSend { "device":"0x1234", "endpoint":"0x03", "send":{"Power":true} } // ZbSend { "device":"0x1234", "endpoint":"0x03", "send":{"Power":"true"} } // ZbSend { "device":"0x1234", "endpoint":"0x03", "send":{"ShutterClose":null} } // ZbSend { "device":"0x1234", "endpoint":"0x03", "send":{"Power":1} } // ZbSend { "device":"0x1234", "endpoint":"0x03", "send":{"Color":"1,2"} } // ZbSend { "device":"0x1234", "endpoint":"0x03", "send":{"Color":"0x1122,0xFFEE"} } if (zigbee.init_phase) { ResponseCmndChar_P(PSTR(D_ZIGBEE_NOT_STARTED)); return; } DynamicJsonBuffer jsonBuf; const JsonObject &json = jsonBuf.parseObject((const char*) XdrvMailbox.data); if (!json.success()) { ResponseCmndChar_P(PSTR(D_JSON_INVALID_JSON)); return; } // params uint16_t device = BAD_SHORTADDR; // BAD_SHORTADDR is broadcast, so considered invalid uint16_t groupaddr = 0x0000; // group address valid only if device == BAD_SHORTADDR uint16_t cluster = 0xFFFF; // no default uint8_t endpoint = 0x00; // 0x00 is invalid for the dst endpoint uint16_t manuf = 0x0000; // Manuf Id in ZCL frame // parse "Device" and "Group" const JsonVariant &val_device = GetCaseInsensitive(json, PSTR(D_CMND_ZIGBEE_DEVICE)); if (nullptr != &val_device) { device = zigbee_devices.parseDeviceParam(val_device.as()); if (BAD_SHORTADDR == device) { ResponseCmndChar_P(PSTR("Invalid parameter")); return; } } if (BAD_SHORTADDR == device) { // if not found, check if we have a group const JsonVariant &val_group = GetCaseInsensitive(json, PSTR(D_CMND_ZIGBEE_GROUP)); if (nullptr != &val_group) { groupaddr = strToUInt(val_group); } else { // no device nor group ResponseCmndChar_P(PSTR("Unknown device")); return; } } // from here, either device has a device shortaddr, or if BAD_SHORTADDR then use group address // Note: groupaddr == 0 is valid // read other parameters const JsonVariant &val_cluster = GetCaseInsensitive(json, PSTR(D_CMND_ZIGBEE_CLUSTER)); if (nullptr != &val_cluster) { cluster = strToUInt(val_cluster); } const JsonVariant &val_endpoint = GetCaseInsensitive(json, PSTR(D_CMND_ZIGBEE_ENDPOINT)); if (nullptr != &val_endpoint) { endpoint = strToUInt(val_endpoint); } const JsonVariant &val_manuf = GetCaseInsensitive(json, PSTR(D_CMND_ZIGBEE_MANUF)); if (nullptr != &val_manuf) { manuf = strToUInt(val_manuf); } // infer endpoint if (BAD_SHORTADDR == device) { endpoint = 0xFF; // endpoint not used for group addresses, so use a dummy broadcast endpoint } else if (0 == endpoint) { // if it was not already specified, try to guess it endpoint = zigbee_devices.findFirstEndpoint(device); AddLog_P2(LOG_LEVEL_DEBUG, PSTR("ZIG: guessing endpoint %d"), endpoint); } if (0 == endpoint) { // after this, if it is still zero, then it's an error ResponseCmndChar_P(PSTR("Missing endpoint")); return; } // from here endpoint is valid and non-zero // cluster may be already specified or 0xFFFF const JsonVariant &val_cmd = GetCaseInsensitive(json, PSTR(D_CMND_ZIGBEE_SEND)); const JsonVariant &val_read = GetCaseInsensitive(json, PSTR(D_CMND_ZIGBEE_READ)); const JsonVariant &val_write = GetCaseInsensitive(json, PSTR(D_CMND_ZIGBEE_WRITE)); const JsonVariant &val_publish = GetCaseInsensitive(json, PSTR(D_CMND_ZIGBEE_REPORT)); const JsonVariant &val_response = GetCaseInsensitive(json, PSTR(D_CMND_ZIGBEE_RESPONSE)); const JsonVariant &val_read_config = GetCaseInsensitive(json, PSTR(D_CMND_ZIGBEE_READ_CONFIG)); const JsonVariant &val_config = GetCaseInsensitive(json, PSTR(D_CMND_ZIGBEE_CONFIG)); uint32_t multi_cmd = (nullptr != &val_cmd) + (nullptr != &val_read) + (nullptr != &val_write) + (nullptr != &val_publish) + (nullptr != &val_response) + (nullptr != &val_read_config) + (nullptr != &val_config); if (multi_cmd > 1) { ResponseCmndChar_P(PSTR("Can only have one of: 'Send', 'Read', 'Write', 'Report', 'Reponse', 'ReadConfig' or 'Config'")); return; } // from here we have one and only one command if (nullptr != &val_cmd) { // "Send":{...commands...} // we accept either a string or a JSON object ZbSendSend(val_cmd, device, groupaddr, cluster, endpoint, manuf); } else if (nullptr != &val_read) { // "Read":{...attributes...}, "Read":attribute or "Read":[...attributes...] // we accept eitehr a number, a string, an array of numbers/strings, or a JSON object ZbSendRead(val_read, device, groupaddr, cluster, endpoint, manuf, ZCL_READ_ATTRIBUTES); } else if (nullptr != &val_write) { // only KSON object if (!val_write.is()) { ResponseCmndChar_P(PSTR("Missing parameters")); return; } // "Write":{...attributes...} ZbSendReportWrite(val_write, device, groupaddr, cluster, endpoint, manuf, ZCL_WRITE_ATTRIBUTES); } else if (nullptr != &val_publish) { // "Publish":{...attributes...} // only KSON object if (!val_publish.is()) { ResponseCmndChar_P(PSTR("Missing parameters")); return; } ZbSendReportWrite(val_publish, device, groupaddr, cluster, endpoint, manuf, ZCL_REPORT_ATTRIBUTES); } else if (nullptr != &val_response) { // "Report":{...attributes...} // only KSON object if (!val_response.is()) { ResponseCmndChar_P(PSTR("Missing parameters")); return; } ZbSendReportWrite(val_response, device, groupaddr, cluster, endpoint, manuf, ZCL_READ_ATTRIBUTES_RESPONSE); } else if (nullptr != &val_read_config) { // "ReadConfg":{...attributes...}, "ReadConfg":attribute or "ReadConfg":[...attributes...] // we accept eitehr a number, a string, an array of numbers/strings, or a JSON object ZbSendRead(val_read_config, device, groupaddr, cluster, endpoint, manuf, ZCL_READ_REPORTING_CONFIGURATION); } else if (nullptr != &val_config) { // "Config":{...attributes...} // only JSON object if (!val_config.is()) { ResponseCmndChar_P(PSTR("Missing parameters")); return; } ZbSendReportWrite(val_config, device, groupaddr, cluster, endpoint, manuf, ZCL_CONFIGURE_REPORTING); } else { Response_P(PSTR("Missing zigbee 'Send', 'Write', 'Report' or 'Response'")); return; } } // // Command `ZbBind` // void ZbBindUnbind(bool unbind) { // false = bind, true = unbind // ZbBind {"Device":"", "Endpoint":, "Cluster":, "ToDevice":"", "ToEndpoint":, "ToGroup": } // ZbUnbind {"Device":"", "Endpoint":, "Cluster":, "ToDevice":"", "ToEndpoint":, "ToGroup": } // local endpoint is always 1, IEEE addresses are calculated if (zigbee.init_phase) { ResponseCmndChar_P(PSTR(D_ZIGBEE_NOT_STARTED)); return; } DynamicJsonBuffer jsonBuf; const JsonObject &json = jsonBuf.parseObject((const char*) XdrvMailbox.data); if (!json.success()) { ResponseCmndChar_P(PSTR(D_JSON_INVALID_JSON)); return; } // params uint16_t srcDevice = BAD_SHORTADDR; // BAD_SHORTADDR is broadcast, so considered invalid uint16_t dstDevice = BAD_SHORTADDR; // BAD_SHORTADDR is broadcast, so considered invalid uint64_t dstLongAddr = 0; uint8_t endpoint = 0x00; // 0x00 is invalid for the src endpoint uint8_t toendpoint = 0x00; // 0x00 is invalid for the dst endpoint uint16_t toGroup = 0x0000; // group address uint16_t cluster = 0; // 0xFFFF is invalid uint32_t group = 0xFFFFFFFF; // 16 bits values, otherwise 0xFFFFFFFF is unspecified // Information about source device: "Device", "Endpoint", "Cluster" // - the source endpoint must have a known IEEE address const JsonVariant &val_device = GetCaseInsensitive(json, PSTR(D_CMND_ZIGBEE_DEVICE)); if (nullptr != &val_device) { srcDevice = zigbee_devices.parseDeviceParam(val_device.as()); } if ((nullptr == &val_device) || (BAD_SHORTADDR == srcDevice)) { ResponseCmndChar_P(PSTR("Unknown source device")); return; } // check if IEEE address is known uint64_t srcLongAddr = zigbee_devices.getDeviceLongAddr(srcDevice); if (0 == srcLongAddr) { ResponseCmndChar_P(PSTR("Unknown source IEEE address")); return; } // look for source endpoint const JsonVariant &val_endpoint = GetCaseInsensitive(json, PSTR(D_CMND_ZIGBEE_ENDPOINT)); if (nullptr != &val_endpoint) { endpoint = strToUInt(val_endpoint); } else { endpoint = zigbee_devices.findFirstEndpoint(srcDevice); } // look for source cluster const JsonVariant &val_cluster = GetCaseInsensitive(json, PSTR(D_CMND_ZIGBEE_CLUSTER)); if (nullptr != &val_cluster) { cluster = strToUInt(val_cluster); // first convert as number if (0 == cluster) { zigbeeFindAttributeByName(val_cluster.as(), &cluster, nullptr, nullptr, nullptr); } } // Or Group Address - we don't need a dstEndpoint in this case const JsonVariant &to_group = GetCaseInsensitive(json, PSTR("ToGroup")); if (nullptr != &to_group) { toGroup = strToUInt(to_group); } // Either Device address // In this case the following parameters are mandatory // - "ToDevice" and the device must have a known IEEE address // - "ToEndpoint" const JsonVariant &dst_device = GetCaseInsensitive(json, PSTR("ToDevice")); // If no target is specified, we default to coordinator 0x0000 if ((nullptr == &to_group) && (nullptr == &dst_device)) { dstDevice = 0x0000; } if ((nullptr != &dst_device) || (BAD_SHORTADDR != dstDevice)) { if (BAD_SHORTADDR == dstDevice) { dstDevice = zigbee_devices.parseDeviceParam(dst_device.as()); if (BAD_SHORTADDR == dstDevice) { ResponseCmndChar_P(PSTR("Invalid parameter")); return; } } if (0x0000 == dstDevice) { dstLongAddr = localIEEEAddr; } else { dstLongAddr = zigbee_devices.getDeviceLongAddr(dstDevice); } if (0 == dstLongAddr) { ResponseCmndChar_P(PSTR("Unknown dest IEEE address")); return; } const JsonVariant &val_toendpoint = GetCaseInsensitive(json, PSTR("ToEndpoint")); if (nullptr != &val_toendpoint) { toendpoint = strToUInt(val_toendpoint); } else { toendpoint = 0x01; } // default to endpoint 1 } // make sure we don't have conflicting parameters if (&to_group && dstLongAddr) { ResponseCmndChar_P(PSTR("Cannot have both \"ToDevice\" and \"ToGroup\"")); return; } if (!&to_group && !dstLongAddr) { ResponseCmndChar_P(PSTR("Missing \"ToDevice\" or \"ToGroup\"")); return; } #ifdef USE_ZIGBEE_ZNP SBuffer buf(34); buf.add8(Z_SREQ | Z_ZDO); if (unbind) { buf.add8(ZDO_UNBIND_REQ); } else { buf.add8(ZDO_BIND_REQ); } buf.add16(srcDevice); buf.add64(srcLongAddr); buf.add8(endpoint); buf.add16(cluster); if (dstLongAddr) { buf.add8(Z_Addr_IEEEAddress); // DstAddrMode - 0x03 = ADDRESS_64_BIT buf.add64(dstLongAddr); buf.add8(toendpoint); } else { buf.add8(Z_Addr_Group); // DstAddrMode - 0x01 = GROUP_ADDRESS buf.add16(toGroup); } ZigbeeZNPSend(buf.getBuffer(), buf.len()); #endif // USE_ZIGBEE_ZNP #ifdef USE_ZIGBEE_EZSP SBuffer buf(24); // ZDO message payload (see Zigbee spec 2.4.3.2.2) buf.add64(srcLongAddr); buf.add8(endpoint); buf.add16(cluster); if (dstLongAddr) { buf.add8(Z_Addr_IEEEAddress); // DstAddrMode - 0x03 = ADDRESS_64_BIT buf.add64(dstLongAddr); buf.add8(toendpoint); } else { buf.add8(Z_Addr_Group); // DstAddrMode - 0x01 = GROUP_ADDRESS buf.add16(toGroup); } EZ_SendZDO(srcDevice, unbind ? ZDO_UNBIND_REQ : ZDO_BIND_REQ, buf.buf(), buf.len()); #endif // USE_ZIGBEE_EZSP ResponseCmndDone(); } // // Command ZbBind // void CmndZbBind(void) { ZbBindUnbind(false); } // // Command ZbBind // void CmndZbUnbind(void) { ZbBindUnbind(true); } // // Command `ZbBindState` // `ZbBindState` as index if it does not fit. If default, `1` starts at the beginning // void CmndZbBindState(void) { if (zigbee.init_phase) { ResponseCmndChar_P(PSTR(D_ZIGBEE_NOT_STARTED)); return; } uint16_t shortaddr = zigbee_devices.parseDeviceParam(XdrvMailbox.data); if (BAD_SHORTADDR == shortaddr) { ResponseCmndChar_P(PSTR("Unknown device")); return; } uint8_t index = XdrvMailbox.index - 1; // change default 1 to 0 #ifdef USE_ZIGBEE_ZNP SBuffer buf(10); buf.add8(Z_SREQ | Z_ZDO); // 25 buf.add8(ZDO_MGMT_BIND_REQ); // 33 buf.add16(shortaddr); // shortaddr buf.add8(index); // StartIndex = 0 ZigbeeZNPSend(buf.getBuffer(), buf.len()); #endif // USE_ZIGBEE_ZNP #ifdef USE_ZIGBEE_EZSP // ZDO message payload (see Zigbee spec 2.4.3.3.4) uint8_t buf[] = { index }; // index = 0 EZ_SendZDO(shortaddr, ZDO_Mgmt_Bind_req, buf, sizeof(buf)); #endif // USE_ZIGBEE_EZSP ResponseCmndDone(); } // Probe a specific device to get its endpoints and supported clusters void CmndZbProbe(void) { CmndZbProbeOrPing(true); } // // Common code for `ZbProbe` and `ZbPing` // void CmndZbProbeOrPing(boolean probe) { if (zigbee.init_phase) { ResponseCmndChar_P(PSTR(D_ZIGBEE_NOT_STARTED)); return; } uint16_t shortaddr = zigbee_devices.parseDeviceParam(XdrvMailbox.data); if (BAD_SHORTADDR == shortaddr) { ResponseCmndChar_P(PSTR("Unknown device")); return; } // everything is good, we can send the command Z_SendIEEEAddrReq(shortaddr); if (probe) { Z_SendActiveEpReq(shortaddr); } ResponseCmndDone(); } // Ping a device, actually a simplified version of ZbProbe void CmndZbPing(void) { CmndZbProbeOrPing(false); } // // Command `ZbName` // Specify, read or erase a Friendly Name // void CmndZbName(void) { // Syntax is: // ZbName , - assign a friendly name // ZbName - display the current friendly name // ZbName , - remove friendly name // // Where can be: short_addr, long_addr, device_index, friendly_name if (zigbee.init_phase) { ResponseCmndChar_P(PSTR(D_ZIGBEE_NOT_STARTED)); return; } // check if parameters contain a comma ',' char *p; char *str = strtok_r(XdrvMailbox.data, ", ", &p); // parse first part, uint16_t shortaddr = zigbee_devices.parseDeviceParam(XdrvMailbox.data, true); // in case of short_addr, it must be already registered if (BAD_SHORTADDR == shortaddr) { ResponseCmndChar_P(PSTR("Unknown device")); return; } if (p == nullptr) { const char * friendlyName = zigbee_devices.getFriendlyName(shortaddr); Response_P(PSTR("{\"0x%04X\":{\"" D_JSON_ZIGBEE_NAME "\":\"%s\"}}"), shortaddr, friendlyName ? friendlyName : ""); } else { if (strlen(p) > 32) { p[32] = 0x00; } // truncate to 32 chars max zigbee_devices.setFriendlyName(shortaddr, p); Response_P(PSTR("{\"0x%04X\":{\"" D_JSON_ZIGBEE_NAME "\":\"%s\"}}"), shortaddr, p); } } // // Command `ZbName` // Specify, read or erase a ModelId, only for debug purposes // void CmndZbModelId(void) { // Syntax is: // ZbName , - assign a friendly name // ZbName - display the current friendly name // ZbName , - remove friendly name // // Where can be: short_addr, long_addr, device_index, friendly_name if (zigbee.init_phase) { ResponseCmndChar_P(PSTR(D_ZIGBEE_NOT_STARTED)); return; } // check if parameters contain a comma ',' char *p; char *str = strtok_r(XdrvMailbox.data, ", ", &p); // parse first part, uint16_t shortaddr = zigbee_devices.parseDeviceParam(XdrvMailbox.data, true); // in case of short_addr, it must be already registered if (BAD_SHORTADDR == shortaddr) { ResponseCmndChar_P(PSTR("Unknown device")); return; } if (p == nullptr) { const char * modelId = zigbee_devices.getModelId(shortaddr); Response_P(PSTR("{\"0x%04X\":{\"" D_JSON_ZIGBEE_MODELID "\":\"%s\"}}"), shortaddr, modelId ? modelId : ""); } else { zigbee_devices.setModelId(shortaddr, p); Response_P(PSTR("{\"0x%04X\":{\"" D_JSON_ZIGBEE_MODELID "\":\"%s\"}}"), shortaddr, p); } } // // Command `ZbLight` // Specify, read or erase a Light type for Hue/Alexa integration void CmndZbLight(void) { // Syntax is: // ZbLight , - assign a bulb type 0-5 // ZbLight - display the current bulb type and status // // Where can be: short_addr, long_addr, device_index, friendly_name if (zigbee.init_phase) { ResponseCmndChar_P(PSTR(D_ZIGBEE_NOT_STARTED)); return; } // check if parameters contain a comma ',' char *p; char *str = strtok_r(XdrvMailbox.data, ", ", &p); // parse first part, uint16_t shortaddr = zigbee_devices.parseDeviceParam(XdrvMailbox.data, true); // in case of short_addr, it must be already registered if (BAD_SHORTADDR == shortaddr) { ResponseCmndChar_P(PSTR("Unknown device")); return; } if (p) { int8_t bulbtype = strtol(p, nullptr, 10); if (bulbtype > 5) { bulbtype = 5; } if (bulbtype < -1) { bulbtype = -1; } zigbee_devices.setHueBulbtype(shortaddr, bulbtype); } String dump = zigbee_devices.dumpLightState(shortaddr); Response_P(PSTR("{\"" D_PRFX_ZB D_CMND_ZIGBEE_LIGHT "\":%s}"), dump.c_str()); MqttPublishPrefixTopicRulesProcess_P(RESULT_OR_STAT, PSTR(D_PRFX_ZB D_CMND_ZIGBEE_LIGHT)); ResponseCmndDone(); } // // Command `ZbForget` // Remove an old Zigbee device from the list of known devices, use ZigbeeStatus to know all registered devices // void CmndZbForget(void) { if (zigbee.init_phase) { ResponseCmndChar_P(PSTR(D_ZIGBEE_NOT_STARTED)); return; } uint16_t shortaddr = zigbee_devices.parseDeviceParam(XdrvMailbox.data); if (BAD_SHORTADDR == shortaddr) { ResponseCmndChar_P(PSTR("Unknown device")); return; } // everything is good, we can send the command if (zigbee_devices.removeDevice(shortaddr)) { ResponseCmndDone(); } else { ResponseCmndChar_P(PSTR("Unknown device")); } } // // Command `ZbSave` // Save Zigbee information to flash // void CmndZbSave(void) { if (zigbee.init_phase) { ResponseCmndChar_P(PSTR(D_ZIGBEE_NOT_STARTED)); return; } saveZigbeeDevices(); ResponseCmndDone(); } // Restore a device configuration previously exported via `ZbStatus2`` // Format: // Either the entire `ZbStatus3` export, or an array or just the device configuration. // If array, if can contain multiple devices // ZbRestore {"ZbStatus3":[{"Device":"0x5ADF","Name":"Petite_Lampe","IEEEAddr":"0x90FD9FFFFE03B051","ModelId":"TRADFRI bulb E27 WS opal 980lm","Manufacturer":"IKEA of Sweden","Endpoints":["0x01","0xF2"]}]} // ZbRestore [{"Device":"0x5ADF","Name":"Petite_Lampe","IEEEAddr":"0x90FD9FFFFE03B051","ModelId":"TRADFRI bulb E27 WS opal 980lm","Manufacturer":"IKEA of Sweden","Endpoints":["0x01","0xF2"]}] // ZbRestore {"Device":"0x5ADF","Name":"Petite_Lampe","IEEEAddr":"0x90FD9FFFFE03B051","ModelId":"TRADFRI bulb E27 WS opal 980lm","Manufacturer":"IKEA of Sweden","Endpoints":["0x01","0xF2"]} void CmndZbRestore(void) { if (zigbee.init_phase) { ResponseCmndChar_P(PSTR(D_ZIGBEE_NOT_STARTED)); return; } DynamicJsonBuffer jsonBuf; const JsonVariant json_parsed = jsonBuf.parse((const char*) XdrvMailbox.data); // const to force a copy of parameter const JsonVariant * json = &json_parsed; // root of restore, to be changed if needed bool success = false; // check if parsing succeeded if (json_parsed.is()) { success = json_parsed.as().success(); } else if (json_parsed.is()) { success = json_parsed.as().success(); } if (!success) { ResponseCmndChar_P(PSTR(D_JSON_INVALID_JSON)); return; } // Check is root contains `ZbStatus` key, if so change the root const JsonVariant * zbstatus = &startsWithCaseInsensitive(*json, PSTR("ZbStatus")); if (nullptr != zbstatus) { json = zbstatus; } // check if the root is an array if (json->is()) { const JsonArray& arr = json->as(); for (auto elt : arr) { // call restore on each item int32_t res = zigbee_devices.deviceRestore(elt); if (res < 0) { ResponseCmndChar_P(PSTR("Restore failed")); return; } } } else if (json->is()) { int32_t res = zigbee_devices.deviceRestore(*json); if (res < 0) { ResponseCmndChar_P(PSTR("Restore failed")); return; } // call restore on a single object } else { ResponseCmndChar_P(PSTR("Missing parameters")); return; } ResponseCmndDone(); } // // Command `ZbPermitJoin` // Allow or Deny pairing of new Zigbee devices // void CmndZbPermitJoin(void) { if (zigbee.init_phase) { ResponseCmndChar_P(PSTR(D_ZIGBEE_NOT_STARTED)); return; } uint32_t payload = XdrvMailbox.payload; uint8_t duration = 60; // default 60s if (payload <= 0) { duration = 0; } // ZNP Version #ifdef USE_ZIGBEE_ZNP if (99 == payload) { duration = 0xFF; // unlimited time } uint16_t dstAddr = 0xFFFC; // default addr SBuffer buf(34); buf.add8(Z_SREQ | Z_ZDO); // 25 buf.add8(ZDO_MGMT_PERMIT_JOIN_REQ); // 36 buf.add8(0x0F); // AddrMode buf.add16(0xFFFC); // DstAddr buf.add8(duration); buf.add8(0x00); // TCSignificance ZigbeeZNPSend(buf.getBuffer(), buf.len()); #endif // USE_ZIGBEE_ZNP // EZSP VERSION #ifdef USE_ZIGBEE_EZSP if (99 == payload) { ResponseCmndChar_P(PSTR("Unlimited time not supported")); return; } SBuffer buf(3); buf.add16(EZSP_permitJoining); buf.add8(duration); ZigbeeEZSPSendCmd(buf.getBuffer(), buf.len()); // send ZDO_Mgmt_Permit_Joining_req to all routers buf.setLen(0); buf.add8(duration); buf.add8(0x01); // TC_Significance - This field shall always have a value of 1, indicating a request to change the Trust Center policy. If a frame is received with a value of 0, it shall be treated as having a value of 1. EZ_SendZDO(0xFFFC, ZDO_Mgmt_Permit_Joining_req, buf.buf(), buf.len()); #endif // USE_ZIGBEE_EZSP ResponseCmndDone(); } #ifdef USE_ZIGBEE_EZSP // // `ZbListen`: add a multicast group to listen to // Overcomes a current limitation that EZSP only shows messages from multicast groups it listens too // // Ex: `ZbListen 99`, `ZbListen2 100` void CmndZbEZSPListen(void) { if (zigbee.init_phase) { ResponseCmndChar_P(PSTR(D_ZIGBEE_NOT_STARTED)); return; } int32_t index = XdrvMailbox.index; // 0 is reserved for group 0 (auto-config) int32_t group = XdrvMailbox.payload; if (group <= 0) { group = 0; } else if (group > 0xFFFF) { group = 0xFFFF; } SBuffer buf(8); buf.add16(EZSP_setMulticastTableEntry); buf.add8(index); buf.add16(group); // group buf.add8(0x01); // endpoint buf.add8(0x00); // network index ZigbeeEZSPSendCmd(buf.getBuffer(), buf.len()); ResponseCmndDone(); } #endif // USE_ZIGBEE_EZSP // // Command `ZbStatus` // void CmndZbStatus(void) { if (ZigbeeSerial) { if (zigbee.init_phase) { ResponseCmndChar_P(PSTR(D_ZIGBEE_NOT_STARTED)); return; } uint16_t shortaddr = zigbee_devices.parseDeviceParam(XdrvMailbox.data); if (XdrvMailbox.payload > 0) { if (BAD_SHORTADDR == shortaddr) { ResponseCmndChar_P(PSTR("Unknown device")); return; } } String dump = zigbee_devices.dump(XdrvMailbox.index, shortaddr); Response_P(PSTR("{\"%s%d\":%s}"), XdrvMailbox.command, XdrvMailbox.index, dump.c_str()); } } // // Command `ZbConfig` // void CmndZbConfig(void) { // ZbConfig // ZbConfig {"Channel":11,"PanID":"0x1A63","ExtPanID":"0xCCCCCCCCCCCCCCCC","KeyL":"0x0F0D0B0907050301L","KeyH":"0x0D0C0A0806040200L"} uint8_t zb_channel = Settings.zb_channel; uint16_t zb_pan_id = Settings.zb_pan_id; uint64_t zb_ext_panid = Settings.zb_ext_panid; uint64_t zb_precfgkey_l = Settings.zb_precfgkey_l; uint64_t zb_precfgkey_h = Settings.zb_precfgkey_h; uint8_t zb_txradio_dbm = Settings.zb_txradio_dbm; // if (zigbee.init_phase) { ResponseCmndChar_P(PSTR(D_ZIGBEE_NOT_STARTED)); return; } RemoveAllSpaces(XdrvMailbox.data); if (strlen(XdrvMailbox.data) > 0) { DynamicJsonBuffer jsonBuf; const JsonObject &json = jsonBuf.parseObject((const char*) XdrvMailbox.data); if (!json.success()) { ResponseCmndChar_P(PSTR(D_JSON_INVALID_JSON)); return; } // Channel const JsonVariant &val_channel = GetCaseInsensitive(json, PSTR("Channel")); if (nullptr != &val_channel) { zb_channel = strToUInt(val_channel); } if (zb_channel < 11) { zb_channel = 11; } if (zb_channel > 26) { zb_channel = 26; } // PanID const JsonVariant &val_pan_id = GetCaseInsensitive(json, PSTR("PanID")); if (nullptr != &val_pan_id) { zb_pan_id = strToUInt(val_pan_id); } // ExtPanID const JsonVariant &val_ext_pan_id = GetCaseInsensitive(json, PSTR("ExtPanID")); if (nullptr != &val_ext_pan_id) { zb_ext_panid = strtoull(val_ext_pan_id.as(), nullptr, 0); } // KeyL const JsonVariant &val_key_l = GetCaseInsensitive(json, PSTR("KeyL")); if (nullptr != &val_key_l) { zb_precfgkey_l = strtoull(val_key_l.as(), nullptr, 0); } // KeyH const JsonVariant &val_key_h = GetCaseInsensitive(json, PSTR("KeyH")); if (nullptr != &val_key_h) { zb_precfgkey_h = strtoull(val_key_h.as(), nullptr, 0); } // TxRadio dBm const JsonVariant &val_txradio = GetCaseInsensitive(json, PSTR("TxRadio")); if (nullptr != &val_txradio) { zb_txradio_dbm = strToUInt(val_txradio); } // Check if a parameter was changed after all if ( (zb_channel != Settings.zb_channel) || (zb_pan_id != Settings.zb_pan_id) || (zb_ext_panid != Settings.zb_ext_panid) || (zb_precfgkey_l != Settings.zb_precfgkey_l) || (zb_precfgkey_h != Settings.zb_precfgkey_h) || (zb_txradio_dbm != Settings.zb_txradio_dbm) ) { Settings.zb_channel = zb_channel; Settings.zb_pan_id = zb_pan_id; Settings.zb_ext_panid = zb_ext_panid; Settings.zb_precfgkey_l = zb_precfgkey_l; Settings.zb_precfgkey_h = zb_precfgkey_h; Settings.zb_txradio_dbm = zb_txradio_dbm; restart_flag = 2; // save and reboot } } // display the current or new configuration char hex_ext_panid[20] = "0x"; Uint64toHex(zb_ext_panid, &hex_ext_panid[2], 64); char hex_precfgkey_l[20] = "0x"; Uint64toHex(zb_precfgkey_l, &hex_precfgkey_l[2], 64); char hex_precfgkey_h[20] = "0x"; Uint64toHex(zb_precfgkey_h, &hex_precfgkey_h[2], 64); // {"ZbConfig":{"Channel":11,"PanID":"0x1A63","ExtPanID":"0xCCCCCCCCCCCCCCCC","KeyL":"0x0F0D0B0907050301L","KeyH":"0x0D0C0A0806040200L"}} Response_P(PSTR("{\"" D_PRFX_ZB D_JSON_ZIGBEE_CONFIG "\":{" "\"Channel\":%d" ",\"PanID\":\"0x%04X\"" ",\"ExtPanID\":\"%s\"" ",\"KeyL\":\"%s\"" ",\"KeyH\":\"%s\"" ",\"TxRadio\":%d" "}}"), zb_channel, zb_pan_id, hex_ext_panid, hex_precfgkey_l, hex_precfgkey_h, zb_txradio_dbm); } /*********************************************************************************************\ * Presentation \*********************************************************************************************/ extern "C" { int device_cmp(const void * a, const void * b) { const Z_Device &dev_a = zigbee_devices.devicesAt(*(uint8_t*)a); const Z_Device &dev_b = zigbee_devices.devicesAt(*(uint8_t*)b); const char * fn_a = dev_a.friendlyName; const char * fn_b = dev_b.friendlyName; if (fn_a && fn_b) { return strcasecmp(fn_a, fn_b); } else if (!fn_a && !fn_b) { return (int32_t)dev_a.shortaddr - (int32_t)dev_b.shortaddr; } else { if (fn_a) return -1; return 1; } } } void ZigbeeShow(bool json) { if (json) { return; #ifdef USE_WEBSERVER } else { uint32_t zigbee_num = zigbee_devices.devicesSize(); if (!zigbee_num) { return; } if (zigbee_num > 255) { zigbee_num = 255; } // Calculate fixed column width for best visual result (Theos opinion) const uint8_t px_batt = 30; // Battery icon is 20px, add 10px as separator const uint8_t px_lqi = (strlen(D_LQI) + 4) * 10; // LQI 254 = 70px WSContentSend_P(PSTR("{t}")); // Terminate current two column table and open new table WSContentSend_P(PSTR("")); // sort elements by name, then by id uint8_t sorted_idx[zigbee_num]; for (uint32_t i = 0; i < zigbee_num; i++) { sorted_idx[i] = i; } qsort(sorted_idx, zigbee_num, sizeof(sorted_idx[0]), device_cmp); for (uint32_t i = 0; i < zigbee_num; i++) { const Z_Device &device = zigbee_devices.devicesAt(sorted_idx[i]); uint16_t shortaddr = device.shortaddr; { // exxplicit scope to free up stack allocated strings char *name = (char*) device.friendlyName; char sdevice[33]; if (nullptr == name) { snprintf_P(sdevice, sizeof(sdevice), PSTR(D_DEVICE " 0x%04X"), shortaddr); name = sdevice; } char slqi[8]; snprintf_P(slqi, sizeof(slqi), PSTR("-")); if (device.validLqi()) { snprintf_P(slqi, sizeof(slqi), PSTR("%d"), device.lqi); } char sbatt[64]; snprintf_P(sbatt, sizeof(sbatt), PSTR(" ")); if (device.validBatteryPercent()) { snprintf_P(sbatt, sizeof(sbatt), PSTR(""), device.batterypercent, changeUIntScale(device.batterypercent, 0, 100, 0, 14)); } if (!i) { // First row needs style info WSContentSend_PD(PSTR("%s%s" D_LQI " %s{e}"), name, px_batt, sbatt, px_lqi, slqi); } else { // Following rows don't need style info so reducing ajax package WSContentSend_PD(PSTR("%s%s" D_LQI " %s{e}"), name, sbatt, slqi); } } // Sensor bool temperature_ok = device.validTemperature(); bool humidity_ok = device.validHumidity(); bool pressure_ok = device.validPressure(); if (temperature_ok || humidity_ok || pressure_ok) { WSContentSend_P(PSTR("┆")); if (temperature_ok) { char buf[12]; dtostrf(device.temperature / 10.0f, 3, 1, buf); WSContentSend_PD(PSTR(" ☀️ %s°C"), buf); } if (humidity_ok) { WSContentSend_P(PSTR(" 💧 %d%%"), device.humidity); } if (pressure_ok) { WSContentSend_P(PSTR(" ⛅ %d hPa"), device.pressure); } WSContentSend_P(PSTR("{e}")); } // Light, switches and plugs bool power_ok = device.validPower(); if (power_ok) { uint8_t channels = device.getLightChannels(); if (0xFF == channels) { channels = 5; } // if number of channel is unknown, display all known attributes WSContentSend_P(PSTR("┆ %s"), device.getPower() ? PSTR(D_ON) : PSTR(D_OFF)); if (device.validDimmer() && (channels >= 1)) { WSContentSend_P(PSTR(" 🔅 %d%%"), changeUIntScale(device.dimmer,0,254,0,100)); } if (device.validCT() && ((channels == 2) || (channels == 5))) { uint32_t ct_k = (((1000000 / device.ct) + 25) / 50) * 50; WSContentSend_P(PSTR(" ⚪ %dK"), device.ct, ct_k); } if (device.validHue() && device.validSat() && (channels >= 3)) { uint8_t r,g,b; uint8_t sat = changeUIntScale(device.sat, 0, 254, 0, 255); // scale to 0..255 LightStateClass::HsToRgb(device.hue, sat, &r, &g, &b); WSContentSend_P(PSTR(" #%02X%02X%02X"), r,g,b,r,g,b); } else if (device.validX() && device.validY() && (channels >= 3)) { uint8_t r,g,b; LightStateClass::XyToRgb(device.x / 65535.0f, device.y / 65535.0f, &r, &g, &b); WSContentSend_P(PSTR(" #%02X%02X%02X"), r,g,b,r,g,b); } if (device.validMainsPower() || device.validMainsVoltage()) { WSContentSend_P(PSTR(" ⚡ ")); if (device.validMainsVoltage()) { WSContentSend_P(PSTR(" %dV"), device.mains_voltage); } if (device.validMainsPower()) { WSContentSend_P(PSTR(" %dW"), device.mains_power); } } } } WSContentSend_P(PSTR("{t}")); // Terminate current multi column table and open new table #endif } } /*********************************************************************************************\ * Interface \*********************************************************************************************/ bool Xdrv23(uint8_t function) { bool result = false; if (zigbee.active) { switch (function) { case FUNC_EVERY_50_MSECOND: if (!zigbee.init_phase) { zigbee_devices.runTimer(); } break; case FUNC_LOOP: #ifdef USE_ZIGBEE_EZSP if (ZigbeeUploadXmodem()) { return false; } #endif if (ZigbeeSerial) { ZigbeeInputLoop(); ZigbeeOutputLoop(); // send any outstanding data } if (zigbee.state_machine) { ZigbeeStateMachine_Run(); } break; #ifdef USE_WEBSERVER case FUNC_WEB_SENSOR: ZigbeeShow(false); break; #endif // USE_WEBSERVER case FUNC_PRE_INIT: ZigbeeInit(); break; case FUNC_COMMAND: result = DecodeCommand(kZbCommands, ZigbeeCommand); break; } } return result; } #endif // USE_ZIGBEE