/* support_device_groups.ino - device groups support for Tasmota Copyright (C) 2021 Paul C Diem Device group allow multiple devices to be in a group with power, light brightness, fade and speed settings and other module-specific settings kept in sync across all devices in the group. 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_DEVICE_GROUPS //#define DEVICE_GROUPS_DEBUG #define DGR_MEMBER_TIMEOUT 45000 #define DGR_ANNOUNCEMENT_INTERVAL 60000 #define DEVICE_GROUP_MESSAGE "TASMOTA_DGR" const char kDeviceGroupMessage[] PROGMEM = DEVICE_GROUP_MESSAGE; struct device_group_member { struct device_group_member * flink; IPAddress ip_address; uint16_t received_sequence; uint16_t acked_sequence; uint32_t unicast_count; }; struct device_group { uint32_t next_announcement_time; uint32_t next_ack_check_time; uint32_t member_timeout_time; uint32_t no_status_share; uint16_t outgoing_sequence; uint16_t last_full_status_sequence; uint16_t message_length; uint16_t ack_check_interval; uint8_t message_header_length; uint8_t initial_status_requests_remaining; char group_name[TOPSZ]; uint8_t message[128]; struct device_group_member * device_group_members; #ifdef USE_DEVICE_GROUPS_SEND uint8_t values_8bit[DGR_ITEM_LAST_8BIT]; uint16_t values_16bit[DGR_ITEM_LAST_16BIT - DGR_ITEM_MAX_8BIT - 1]; uint32_t values_32bit[DGR_ITEM_LAST_32BIT - DGR_ITEM_MAX_16BIT - 1]; #endif // USE_DEVICE_GROUPS_SEND }; WiFiUDP device_groups_udp; struct device_group * device_groups; uint32_t next_check_time; bool device_groups_initialized = false; bool device_groups_up = false; bool building_status_message = false; bool ignore_dgr_sends = false; char * IPAddressToString(const IPAddress& ip_address) { static char buffer[16]; sprintf_P(buffer, PSTR("%u.%u.%u.%u"), ip_address[0], ip_address[1], ip_address[2], ip_address[3]); return buffer; } uint8_t * BeginDeviceGroupMessage(struct device_group * device_group, uint16_t flags, bool hold_sequence = false) { uint8_t * message_ptr = &device_group->message[device_group->message_header_length]; if (!hold_sequence && !++device_group->outgoing_sequence) device_group->outgoing_sequence = 1; *message_ptr++ = device_group->outgoing_sequence & 0xff; *message_ptr++ = device_group->outgoing_sequence >> 8; *message_ptr++ = flags & 0xff; *message_ptr++ = flags >> 8; return message_ptr; } uint32_t DeviceGroupSharedMask(uint8_t item) { uint32_t mask = 0; if (item == DGR_ITEM_LIGHT_BRI || item == DGR_ITEM_BRI_POWER_ON) mask = DGR_SHARE_LIGHT_BRI; else if (item == DGR_ITEM_POWER) mask = DGR_SHARE_POWER; else if (item == DGR_ITEM_LIGHT_SCHEME) mask = DGR_SHARE_LIGHT_SCHEME; else if (item == DGR_ITEM_LIGHT_FIXED_COLOR || item == DGR_ITEM_LIGHT_CHANNELS) mask = DGR_SHARE_LIGHT_COLOR; else if (item == DGR_ITEM_LIGHT_FADE || item == DGR_ITEM_LIGHT_SPEED) mask = DGR_SHARE_LIGHT_FADE; else if (item == DGR_ITEM_BRI_PRESET_LOW || item == DGR_ITEM_BRI_PRESET_HIGH) mask = DGR_SHARE_DIMMER_SETTINGS; else if (item == DGR_ITEM_EVENT) mask = DGR_SHARE_EVENT; return mask; } void DeviceGroupsInit(void) { // If no module set the device group count, ... if (!device_group_count) { // If relays in separate device groups is enabled, set the device group count to highest numbered // relay. if (Settings.flag4.multiple_device_groups) { // SetOption88 - Enable relays in separate device groups for (uint32_t relay_index = 0; relay_index < MAX_RELAYS; relay_index++) { if (PinUsed(GPIO_REL1, relay_index)) device_group_count = relay_index + 1; } if (device_group_count > MAX_DEV_GROUP_NAMES) device_group_count = MAX_DEV_GROUP_NAMES; } // Otherwise, set the device group count to 1. else { device_group_count = 1; } } // If there are more device group names set than the number of device groups needed by the // module, use the device group name count as the device group count. for (; device_group_count < MAX_DEV_GROUP_NAMES; device_group_count++) { if (!*SettingsText(SET_DEV_GROUP_NAME1 + device_group_count)) break; } // Initialize the device information for each device group. device_groups = (struct device_group *)calloc(device_group_count, sizeof(struct device_group)); if (!device_groups) { AddLog(LOG_LEVEL_ERROR, PSTR("DGR: Error allocating %u-element array"), device_group_count); return; } struct device_group * device_group = device_groups; for (uint32_t device_group_index = 0; device_group_index < device_group_count; device_group_index++, device_group++) { strcpy(device_group->group_name, SettingsText(SET_DEV_GROUP_NAME1 + device_group_index)); // If the device group name is not set, use the MQTT group topic (with the device group index + // 1 appended for device group indices > 0). if (!device_group->group_name[0]) { strcpy(device_group->group_name, SettingsText(SET_MQTT_GRP_TOPIC)); if (device_group_index) { snprintf_P(device_group->group_name, sizeof(device_group->group_name), PSTR("%s%u"), device_group->group_name, device_group_index + 1); } } device_group->message_header_length = sprintf_P((char *)device_group->message, PSTR("%s%s"), kDeviceGroupMessage, device_group->group_name) + 1; device_group->no_status_share = 0; device_group->last_full_status_sequence = -1; } // If both in and out shared items masks are 0, assume they're unitialized and initialize them. if (!Settings.device_group_share_in && !Settings.device_group_share_out) { Settings.device_group_share_in = Settings.device_group_share_out = 0xffffffff; } device_groups_initialized = true; } void DeviceGroupsStart() { if (Settings.flag4.device_groups_enabled && !device_groups_up && !TasmotaGlobal.restart_flag) { // If we haven't successfuly initialized device groups yet, attempt to do it now. if (!device_groups_initialized) { DeviceGroupsInit(); if (!device_groups_initialized) return; } // Subscribe to device groups multicasts. if (!device_groups_udp.beginMulticast(WiFi.localIP(), IPAddress(DEVICE_GROUPS_ADDRESS), DEVICE_GROUPS_PORT)) { AddLog(LOG_LEVEL_ERROR, PSTR("DGR: Error subscribing")); return; } device_groups_up = true; // The WiFi was down but now it's up and device groups is initialized. (Re-)discover devices in // our device group(s). Load the status request message for all device groups. This message will // be multicast 10 times at 200ms intervals. next_check_time = millis() + 2000; struct device_group * device_group = device_groups; for (uint32_t device_group_index = 0; device_group_index < device_group_count; device_group_index++, device_group++) { device_group->next_announcement_time = -1; device_group->message_length = BeginDeviceGroupMessage(device_group, DGR_FLAG_RESET | DGR_FLAG_STATUS_REQUEST) - device_group->message; device_group->initial_status_requests_remaining = 10; device_group->next_ack_check_time = next_check_time; } AddLog(LOG_LEVEL_DEBUG, PSTR("DGR: (Re)discovering members")); } } void DeviceGroupsStop() { device_groups_udp.flush(); device_groups_up = false; } void SendReceiveDeviceGroupMessage(struct device_group * device_group, struct device_group_member * device_group_member, uint8_t * message, int message_length, bool received) { bool item_processed = false; uint16_t message_sequence; uint16_t flags; int device_group_index = device_group - device_groups; int log_length; int log_remaining; char * log_ptr; // Find the end and start of the actual message (after the header). uint8_t * message_end_ptr = message + message_length; uint8_t * message_ptr = message + strlen((char *)message) + 1; // Get the message sequence and flags. if (message_ptr + 4 > message_end_ptr) return; // Malformed message - must be at least 16-bit sequence, 16-bit flags left message_sequence = *message_ptr++; message_sequence |= *message_ptr++ << 8; flags = *message_ptr++; flags |= *message_ptr++ << 8; // Initialize the log buffer. char * log_buffer = (char *)malloc(512); log_length = sprintf(log_buffer, PSTR("DGR: %s %s message %s %s: seq=%u, flags=%u"), (received ? PSTR("Received") : PSTR("Sending")), device_group->group_name, (received ? PSTR("from") : PSTR("to")), (device_group_member ? IPAddressToString(device_group_member->ip_address) : received ? PSTR("local") : PSTR("network")), message_sequence, flags); log_ptr = log_buffer + log_length; log_remaining = 512 - log_length; // If this is an announcement, just log it. if (flags == DGR_FLAG_ANNOUNCEMENT) goto write_log; // If this is a received ack message, save the message sequence if it's newer than the last ack we // received from this member. if (flags == DGR_FLAG_ACK) { if (received && device_group_member && (message_sequence > device_group_member->acked_sequence || device_group_member->acked_sequence - message_sequence < 64536)) { device_group_member->acked_sequence = message_sequence; } goto write_log; } // If this is a received message, send an ack message to the sender. if (device_group_member) { if (received) { if (!(flags & DGR_FLAG_MORE_TO_COME)) { *(message_ptr - 2) = DGR_FLAG_ACK; *(message_ptr - 1) = 0; SendReceiveDeviceGroupMessage(device_group, device_group_member, message, message_ptr - message, false); } } // If we're sending this message directly to a member, it's a resend. else { log_length = snprintf(log_ptr, log_remaining, PSTR(", last ack=%u"), device_group_member->acked_sequence); log_ptr += log_length; log_remaining -= log_length; goto write_log; } } // If this is a status request message, skip item processing. if ((flags & DGR_FLAG_STATUS_REQUEST)) goto write_log; // If this is a received message, ... if (received) { // If we already processed this or a later message from this group member, ignore this message. if (device_group_member) { if (message_sequence <= device_group_member->received_sequence) { if (message_sequence == device_group_member->received_sequence || device_group_member->received_sequence - message_sequence > 64536) { log_length = snprintf(log_ptr, log_remaining, PSTR(" (old)")); log_ptr += log_length; log_remaining -= log_length; goto write_log; } } device_group_member->received_sequence = message_sequence; } /* XdrvMailbox bool grpflg bool usridx uint16_t command_code Item code uint32_t index 0:15 Flags, 16:31 Message sequence uint32_t data_len String item value length int32_t payload Integer item value char *topic Pointer to device group index char *data Pointer to non-integer item value char *command nullptr */ XdrvMailbox.command = nullptr; // Indicates the source is a device group update XdrvMailbox.index = flags | message_sequence << 16; if (device_group_index == 0 && first_device_group_is_local) XdrvMailbox.index |= DGR_FLAG_LOCAL; XdrvMailbox.topic = (char *)&device_group_index; if (flags & (DGR_FLAG_MORE_TO_COME | DGR_FLAG_DIRECT)) TasmotaGlobal.skip_light_fade = true; // Set the flag to ignore device group send message request so callbacks from the drivers do not // send updates. ignore_dgr_sends = true; } uint8_t item; uint8_t item_flags; int32_t value; uint32_t mask; item_flags = 0; for (;;) { if (message_ptr >= message_end_ptr) goto badmsg; // Malformed message item = *message_ptr++; if (!item) break; // Done #ifdef DEVICE_GROUPS_DEBUG switch (item) { case DGR_ITEM_FLAGS: case DGR_ITEM_LIGHT_FADE: case DGR_ITEM_LIGHT_SPEED: case DGR_ITEM_LIGHT_BRI: case DGR_ITEM_LIGHT_SCHEME: case DGR_ITEM_LIGHT_FIXED_COLOR: case DGR_ITEM_BRI_PRESET_LOW: case DGR_ITEM_BRI_PRESET_HIGH: case DGR_ITEM_BRI_POWER_ON: case DGR_ITEM_POWER: case DGR_ITEM_NO_STATUS_SHARE: case DGR_ITEM_EVENT: case DGR_ITEM_LIGHT_CHANNELS: break; default: AddLog(LOG_LEVEL_ERROR, PSTR("DGR: *** Invalid item=%u"), item); } #endif // DEVICE_GROUPS_DEBUG log_length = snprintf(log_ptr, log_remaining, PSTR(", %u="), item); log_ptr += log_length; log_remaining -= log_length; log_length = 0; if (item <= DGR_ITEM_LAST_32BIT) { value = *message_ptr++; if (item > DGR_ITEM_MAX_8BIT) { value |= *message_ptr++ << 8; if (item > DGR_ITEM_MAX_16BIT) { value |= *message_ptr++ << 16; value |= *message_ptr++ << 24; #ifdef USE_DEVICE_GROUPS_SEND device_group->values_32bit[item - DGR_ITEM_MAX_16BIT - 1] = (item == DGR_ITEM_POWER ? value & 0xffffff : value); #endif // USE_DEVICE_GROUPS_SEND } #ifdef USE_DEVICE_GROUPS_SEND else { device_group->values_16bit[item - DGR_ITEM_MAX_8BIT - 1] = value; } #endif // USE_DEVICE_GROUPS_SEND } #ifdef USE_DEVICE_GROUPS_SEND else { device_group->values_8bit[item] = value; } #endif // USE_DEVICE_GROUPS_SEND log_length = snprintf(log_ptr, log_remaining, PSTR("%u"), value); } else { value = *message_ptr++; if (received) XdrvMailbox.data = (char *)message_ptr; if (message_ptr + value >= message_end_ptr) goto badmsg; // Malformed message if (item <= DGR_ITEM_MAX_STRING) { log_length = snprintf(log_ptr, log_remaining, PSTR("'%s'"), message_ptr); } else { switch (item) { case DGR_ITEM_LIGHT_CHANNELS: log_length = snprintf(log_ptr, log_remaining, PSTR("%u,%u,%u,%u,%u,%u"), *message_ptr, *(message_ptr + 1), *(message_ptr + 2), *(message_ptr + 3), *(message_ptr + 4), *(message_ptr + 5)); break; } } message_ptr += value; } log_ptr += log_length; log_remaining -= log_length; if (received) { if (item == DGR_ITEM_FLAGS) { item_flags = value; continue; } mask = DeviceGroupSharedMask(item); if (item_flags & DGR_ITEM_FLAG_NO_SHARE) device_group->no_status_share |= mask; else device_group->no_status_share &= ~mask; if ((!(device_group->no_status_share & mask) || device_group_member == nullptr) && (!mask || (mask & Settings.device_group_share_in))) { item_processed = true; XdrvMailbox.command_code = item; XdrvMailbox.payload = value; XdrvMailbox.data_len = value; *log_ptr++ = '*'; log_remaining--; switch (item) { case DGR_ITEM_POWER: if (Settings.flag4.multiple_device_groups) { // SetOption88 - Enable relays in separate device groups uint32_t device = Settings.device_group_tie[device_group_index]; if (device) { bool on = (value & 1); if (on != ((TasmotaGlobal.power >> (device - 1)) & 1)) ExecuteCommandPower(device, (on ? POWER_ON : POWER_OFF), SRC_REMOTE); } } else if (XdrvMailbox.index & DGR_FLAG_LOCAL) { uint8_t mask_devices = value >> 24; if (mask_devices > TasmotaGlobal.devices_present) mask_devices = TasmotaGlobal.devices_present; for (uint32_t i = 0; i < mask_devices; i++) { uint32_t mask = 1 << i; bool on = (value & mask); if (on != (TasmotaGlobal.power & mask)) ExecuteCommandPower(i + 1, (on ? POWER_ON : POWER_OFF), SRC_REMOTE); } } break; case DGR_ITEM_NO_STATUS_SHARE: device_group->no_status_share = value; break; #ifdef USE_RULES case DGR_ITEM_EVENT: CmndEvent(); break; #endif case DGR_ITEM_COMMAND: ExecuteCommand(XdrvMailbox.data, SRC_REMOTE); break; } XdrvCall(FUNC_DEVICE_GROUP_ITEM); } item_flags = 0; } if (item_processed) { XdrvMailbox.command_code = DGR_ITEM_EOL; XdrvCall(FUNC_DEVICE_GROUP_ITEM); } } write_log: *log_ptr++ = 0; AddLogData(LOG_LEVEL_DEBUG_MORE, log_buffer); // If this is a received status request message, then if the requestor didn't just ack our // previous full status update, send a full status update. if (received) { if ((flags & DGR_FLAG_STATUS_REQUEST)) { if ((flags & DGR_FLAG_RESET) || device_group_member->acked_sequence != device_group->last_full_status_sequence) { _SendDeviceGroupMessage(-device_group_index, DGR_MSGTYP_FULL_STATUS); } } } // If this is a message being sent, send it. else { int attempt; IPAddress ip_address = (device_group_member ? device_group_member->ip_address : IPAddress(DEVICE_GROUPS_ADDRESS)); for (attempt = 1; attempt <= 5; attempt++) { if (device_groups_udp.beginPacket(ip_address, DEVICE_GROUPS_PORT)) { device_groups_udp.write(message, message_length); if (device_groups_udp.endPacket()) break; } delay(10); } if (attempt > 5) AddLog(LOG_LEVEL_ERROR, PSTR("DGR: Error sending message")); } goto cleanup; badmsg: AddLog(LOG_LEVEL_ERROR, PSTR("%s ** incorrect length"), log_buffer); cleanup: free(log_buffer); if (received) { TasmotaGlobal.skip_light_fade = false; ignore_dgr_sends = false; } } bool _SendDeviceGroupMessage(int32_t device, DevGroupMessageType message_type, ...) { // If device groups is not up, ignore this request. if (!device_groups_up) return 1; // Extract the flags from the message type. bool with_local = ((message_type & DGR_MSGTYPFLAG_WITH_LOCAL) != 0); message_type = (DevGroupMessageType)(message_type & 0x7F); // If we're currently processing a remote device message, ignore this request. if (ignore_dgr_sends && message_type != DGR_MSGTYPE_UPDATE_COMMAND) return 0; // If device is < 0, the device group index is the device negated. If not, get the device group // index for this device. uint8_t device_group_index = -device; if (device > 0) { device_group_index = 0; if (Settings.flag4.multiple_device_groups) { // SetOption88 - Enable relays in separate device groups for (; device_group_index < device_group_count; device_group_index++) { if (Settings.device_group_tie[device_group_index] == device) break; } } } if (device_group_index >= device_group_count) return 0; // Get a pointer to the device information for this device. struct device_group * device_group = &device_groups[device_group_index]; // If we're still sending initial status requests, ignore this request. if (device_group->initial_status_requests_remaining) return 1; // Load the message header, sequence and flags. #ifdef DEVICE_GROUPS_DEBUG AddLog(LOG_LEVEL_DEBUG, PSTR("DGR: Building %s %spacket"), device_group->group_name, (message_type == DGR_MSGTYP_FULL_STATUS ? PSTR("full status ") : PSTR(""))); #endif // DEVICE_GROUPS_DEBUG uint16_t original_sequence = device_group->outgoing_sequence; uint16_t flags = 0; if (message_type == DGR_MSGTYP_UPDATE_MORE_TO_COME) flags = DGR_FLAG_MORE_TO_COME; else if (message_type == DGR_MSGTYP_UPDATE_DIRECT) flags = DGR_FLAG_DIRECT; uint8_t * message_ptr = BeginDeviceGroupMessage(device_group, flags, building_status_message || message_type == DGR_MSGTYP_PARTIAL_UPDATE); // A full status request is a request from a remote device for the status of every item we // control. As long as we're building it, we may as well multicast the status update to all // device group members. if (message_type == DGR_MSGTYP_FULL_STATUS) { device_group->last_full_status_sequence = device_group->outgoing_sequence; device_group->message_length = 0; // Set the flag indicating we're currently building a status message. SendDeviceGroupMessage // will build but not send messages while this flag is set. building_status_message = true; // Call the drivers to build the status update. power_t power = TasmotaGlobal.power; if (Settings.flag4.multiple_device_groups) { // SetOption88 - Enable relays in separate device groups power = (power >> (Settings.device_group_tie[device_group_index] - 1)) & 1; } SendDeviceGroupMessage(-device_group_index, DGR_MSGTYP_PARTIAL_UPDATE, DGR_ITEM_NO_STATUS_SHARE, device_group->no_status_share, DGR_ITEM_POWER, power); XdrvMailbox.index = 0; if (device_group_index == 0 && first_device_group_is_local) XdrvMailbox.index = DGR_FLAG_LOCAL; XdrvMailbox.command_code = DGR_ITEM_STATUS; XdrvMailbox.topic = (char *)&device_group_index; XdrvCall(FUNC_DEVICE_GROUP_ITEM); building_status_message = false; // Set the status update flag in the outgoing message. *(message_ptr - 2) |= DGR_FLAG_FULL_STATUS; // If we have nothing to share with the other members, just send the EOL item. if (!device_group->message_length) { *message_ptr++ = 0; device_group->message_length = message_ptr - device_group->message; } } else { #ifdef USE_DEVICE_GROUPS_SEND uint8_t out_buffer[128]; bool escaped; char chr; char oper; uint32_t old_value; uint8_t * out_ptr = out_buffer; #endif // USE_DEVICE_GROUPS_SEND struct item { uint8_t item; uint8_t flags; uint32_t value; void * value_ptr; } item_array[32]; bool shared; uint8_t item; uint32_t mask; uint32_t value; uint8_t * value_ptr; uint8_t * first_item_ptr = message_ptr; struct item * item_ptr; va_list ap; // Build an array of all the items and values in this update. item_ptr = item_array; #ifdef USE_DEVICE_GROUPS_SEND if (message_type == DGR_MSGTYPE_UPDATE_COMMAND) { value_ptr = (uint8_t *)XdrvMailbox.data; while ((item = strtoul((char *)value_ptr, (char **)&value_ptr, 0))) { item_ptr->item = item; if (*value_ptr != '=') return 1; value_ptr++; // If flags were specified for this item, save them. item_ptr->flags = 0; if (toupper(*value_ptr) == 'N') { value_ptr++; item_ptr->flags = DGR_ITEM_FLAG_NO_SHARE; } if (item <= DGR_ITEM_MAX_32BIT) { oper = 0; if (*value_ptr == '@') { oper = value_ptr[1]; value_ptr += 2; } value = (isdigit(*value_ptr) ? strtoul((char *)value_ptr, (char **)&value_ptr, 0) : oper == '^' ? 0xffffffff : 1); if (oper) { old_value = (item <= DGR_ITEM_MAX_8BIT ? device_group->values_8bit[item] : (item <= DGR_ITEM_MAX_16BIT ? device_group->values_16bit[item - DGR_ITEM_MAX_8BIT - 1] : device_group->values_32bit[item - DGR_ITEM_MAX_16BIT - 1])); value = (oper == '+' ? old_value + value : oper == '-' ? old_value - value : oper == '^' ? old_value ^ value : oper == '|' ? old_value | value : old_value == '&' ? old_value & value : old_value); } item_ptr->value = value; } else { item_ptr->value_ptr = out_ptr; if (item <= DGR_ITEM_MAX_STRING) { escaped = false; while ((chr = *value_ptr++)) { if (chr == ' ' && !escaped) break; if (!(escaped = (chr == '\\' && !escaped))) *out_ptr++ = chr; } *out_ptr++ = 0; } else { switch (item) { case DGR_ITEM_LIGHT_CHANNELS: { bool hex = false; char * endptr; if (*value_ptr == '#') { value_ptr++; hex = true; } for (int i = 0; i < 6; i++) { *out_ptr = 0; if (*value_ptr != ' ') { if (hex) { endptr = (char *)value_ptr + 2; chr = *endptr; *endptr = 0; *out_ptr = strtoul((char *)value_ptr, (char **)&value_ptr, 16); *endptr = chr; } else { *out_ptr = strtoul((char *)value_ptr, (char **)&value_ptr, 10); if (*value_ptr == ',') value_ptr++; } } out_ptr++; } } break; } } } item_ptr++; } } else { #endif // USE_DEVICE_GROUPS_SEND va_start(ap, message_type); while ((item = va_arg(ap, int))) { item_ptr->item = item; item_ptr->flags = 0; if (item <= DGR_ITEM_MAX_32BIT) item_ptr->value = va_arg(ap, int); else if (item <= DGR_ITEM_MAX_STRING) item_ptr->value_ptr = va_arg(ap, char *); else { item_ptr->value_ptr = va_arg(ap, uint8_t *); } item_ptr++; } va_end(ap); #ifdef USE_DEVICE_GROUPS_SEND } #endif // USE_DEVICE_GROUPS_SEND item_ptr->item = 0; // If we're still building this update or all group members haven't acknowledged the previous // update yet, update the message to include these new updates. First we need to rebuild the // previous update message to remove any items and their values that are included in this new // update. if (device_group->message_length) { uint8_t item_flags = 0; int kept_item_count = 0; // Rebuild the previous update message, removing any items whose values are included in this // new update. uint8_t * previous_message_ptr = message_ptr; while (item = *previous_message_ptr++) { // If this is the flags item, save the flags. if (item == DGR_ITEM_FLAGS) { item_flags = *previous_message_ptr++; } // Otherwise, determine the length of this item's value. else { if (item <= DGR_ITEM_MAX_32BIT) { value = 1; if (item > DGR_ITEM_MAX_8BIT) { value = 2; if (item > DGR_ITEM_MAX_16BIT) { value = 4; } } } else { value = *previous_message_ptr + 1; } // Search for this item in the new update. for (item_ptr = item_array; item_ptr->item; item_ptr++) { if (item_ptr->item == item) break; } // If this item was not found in the new update, copy it to the new update message. If the // item has flags, first copy the flags item to the new update message. if (!item_ptr->item) { kept_item_count++; if (item_flags) { *message_ptr++ = DGR_ITEM_FLAGS; *message_ptr++ = item_flags; } *message_ptr++ = item; memmove(message_ptr, previous_message_ptr, value); message_ptr += value; } item_flags = 0; } // Advance past the item value. previous_message_ptr += value; } #ifdef DEVICE_GROUPS_DEBUG AddLog(LOG_LEVEL_DEBUG, PSTR("DGR: %u items carried over"), kept_item_count); #endif // DEVICE_GROUPS_DEBUG } // Itertate through the passed items adding them and their values to the message. for (item_ptr = item_array; (item = item_ptr->item); item_ptr++) { // If this item is shared with the group add it to the message. shared = true; if ((mask = DeviceGroupSharedMask(item))) { if (item_ptr->flags & DGR_ITEM_FLAG_NO_SHARE) device_group->no_status_share |= mask; else if (!building_status_message) device_group->no_status_share &= ~mask; if (message_type != DGR_MSGTYPE_UPDATE_COMMAND) { shared = (!(mask & device_group->no_status_share) && (device_group_index || (mask & Settings.device_group_share_out))); } } if (shared) { if (item_ptr->flags) { *message_ptr++ = DGR_ITEM_FLAGS; *message_ptr++ = item_ptr->flags; } *message_ptr++ = item; // For integer items, add the value to the message. if (item <= DGR_ITEM_MAX_32BIT) { value = item_ptr->value; *message_ptr++ = value & 0xff; if (item > DGR_ITEM_MAX_8BIT) { value >>= 8; *message_ptr++ = value & 0xff; if (item > DGR_ITEM_MAX_16BIT) { value >>= 8; *message_ptr++ = value & 0xff; value >>= 8; // For the power item, the device count is overlayed onto the highest 8 bits. if (item == DGR_ITEM_POWER && !value) value = (!Settings.flag4.multiple_device_groups && device_group_index == 0 && first_device_group_is_local ? TasmotaGlobal.devices_present : 1); *message_ptr++ = value; } } } // For string items and special items, get the value length. else { if (item <= DGR_ITEM_MAX_STRING) { value = strlen((const char *)item_ptr->value_ptr) + 1; } else { switch (item) { case DGR_ITEM_LIGHT_CHANNELS: value = 6; break; } } // Load the length and copy the value. *message_ptr++ = value; memcpy(message_ptr, item_ptr->value_ptr, value); message_ptr += value; } } } // If we added any items, add the EOL item code and calculate the message length. if (message_ptr != first_item_ptr) { *message_ptr++ = 0; device_group->message_length = message_ptr - device_group->message; } // If there's going to be more items added to this message, return. if (building_status_message || message_type == DGR_MSGTYP_PARTIAL_UPDATE) return 0; } // If there is no message, restore the sequence number and return. if (!device_group->message_length) { device_group->outgoing_sequence = original_sequence; return 0; } // Multicast the packet. SendReceiveDeviceGroupMessage(device_group, nullptr, device_group->message, device_group->message_length, false); #ifdef USE_DEVICE_GROUPS_SEND // If requested, handle this updated locally as well. if (with_local) { struct XDRVMAILBOX save_XdrvMailbox = XdrvMailbox; SendReceiveDeviceGroupMessage(device_group, nullptr, device_group->message, device_group->message_length, true); XdrvMailbox = save_XdrvMailbox; } #endif // USE_DEVICE_GROUPS_SEND uint32_t now = millis(); if (message_type == DGR_MSGTYP_UPDATE_MORE_TO_COME) { device_group->message_length = 0; device_group->next_ack_check_time = 0; } else { device_group->ack_check_interval = 200; device_group->next_ack_check_time = now + device_group->ack_check_interval; if (device_group->next_ack_check_time < next_check_time) next_check_time = device_group->next_ack_check_time; device_group->member_timeout_time = now + DGR_MEMBER_TIMEOUT; } device_group->next_announcement_time = now + DGR_ANNOUNCEMENT_INTERVAL; if (device_group->next_announcement_time < next_check_time) next_check_time = device_group->next_announcement_time; return 0; } void ProcessDeviceGroupMessage(uint8_t * message, int message_length) { // Search for a device group with the target group name. If one isn't found, return. uint8_t device_group_index = 0; struct device_group * device_group = device_groups; char * message_group_name = (char *)message + sizeof(DEVICE_GROUP_MESSAGE) - 1; for (;;) { if (!strcmp(message_group_name, device_group->group_name)) break; if (++device_group_index >= device_group_count) return; device_group++; } // Find the group member. If this is a new group member, add it. struct device_group_member * device_group_member; IPAddress remote_ip = device_groups_udp.remoteIP(); struct device_group_member * * flink = &device_group->device_group_members; for (;;) { device_group_member = *flink; if (!device_group_member) { device_group_member = (struct device_group_member *)calloc(1, sizeof(struct device_group_member)); if (device_group_member == nullptr) { AddLog(LOG_LEVEL_ERROR, PSTR("DGR: Error allocating member block")); return; } device_group_member->ip_address = remote_ip; *flink = device_group_member; AddLog(LOG_LEVEL_DEBUG, PSTR("DGR: Member %s added"), IPAddressToString(remote_ip)); break; } else if (device_group_member->ip_address == remote_ip) { break; } flink = &device_group_member->flink; } SendReceiveDeviceGroupMessage(device_group, device_group_member, message, message_length, true); } void DeviceGroupStatus(uint8_t device_group_index) { if (Settings.flag4.device_groups_enabled && device_group_index < device_group_count) { char buffer[1024]; int member_count = 0; struct device_group * device_group = &device_groups[device_group_index]; buffer[0] = buffer[1] = 0; for (struct device_group_member * device_group_member = device_group->device_group_members; device_group_member; device_group_member = device_group_member->flink) { snprintf_P(buffer, sizeof(buffer), PSTR("%s,{\"IPAddress\":\"%s\",\"ResendCount\":%u,\"LastRcvdSeq\":%u,\"LastAckedSeq\":%u}"), buffer, IPAddressToString(device_group_member->ip_address), device_group_member->unicast_count, device_group_member->received_sequence, device_group_member->acked_sequence); member_count++; } Response_P(PSTR("{\"" D_CMND_DEVGROUPSTATUS "\":{\"Index\":%u,\"GroupName\":\"%s\",\"MessageSeq\":%u,\"MemberCount\":%d,\"Members\":[%s]}}"), device_group_index, device_group->group_name, device_group->outgoing_sequence, member_count, &buffer[1]); } } void DeviceGroupsLoop(void) { if (!device_groups_up || TasmotaGlobal.restart_flag) return; while (device_groups_udp.parsePacket()) { uint8_t packet_buffer[512]; int length = device_groups_udp.read(packet_buffer, sizeof(packet_buffer) - 1); if (length > 0) { packet_buffer[length] = 0; if (!strncmp_P((char *)packet_buffer, kDeviceGroupMessage, sizeof(DEVICE_GROUP_MESSAGE) - 1)) { ProcessDeviceGroupMessage(packet_buffer, length); } } } uint32_t now = millis(); // If it's time to check on things, iterate through the device groups. if ((long)(now - next_check_time) >= 0) { #ifdef DEVICE_GROUPS_DEBUG AddLog(LOG_LEVEL_DEBUG, PSTR("DGR: Checking next_check_time=%u, now=%u"), next_check_time, now); #endif // DEVICE_GROUPS_DEBUG next_check_time = now + DGR_ANNOUNCEMENT_INTERVAL * 2; struct device_group * device_group = device_groups; for (uint32_t device_group_index = 0; device_group_index < device_group_count; device_group_index++, device_group++) { // If we're still waiting for acks to the last update from this device group, ... if (device_group->next_ack_check_time) { // If it's time to check for acks, ... if ((long)(now - device_group->next_ack_check_time) >= 0) { // If we're still sending the initial status request message, send it. if (device_group->initial_status_requests_remaining) { if (--device_group->initial_status_requests_remaining) { #ifdef DEVICE_GROUPS_DEBUG AddLog(LOG_LEVEL_DEBUG, PSTR("DGR: Sending initial status request for group %s"), device_group->group_name); #endif // DEVICE_GROUPS_DEBUG SendReceiveDeviceGroupMessage(device_group, nullptr, device_group->message, device_group->message_length, false); device_group->message[device_group->message_header_length + 2] = DGR_FLAG_STATUS_REQUEST; // The reset flag is on only for the first packet - turn it off now next_check_time = device_group->next_ack_check_time = now + 200; continue; } // If we've sent the initial status request message the set number of times, send our // status to all the members. else { _SendDeviceGroupMessage(-device_group_index, DGR_MSGTYP_FULL_STATUS); } } // If we're done initializing, iterate through the group memebers, ... else { #ifdef DEVICE_GROUPS_DEBUG AddLog(LOG_LEVEL_DEBUG, PSTR("DGR: Checking for ack's")); #endif // DEVICE_GROUPS_DEBUG bool acked = true; struct device_group_member ** flink = &device_group->device_group_members; struct device_group_member * device_group_member; while ((device_group_member = *flink)) { // If we have not received an ack to our last message from this member, ... if (device_group_member->acked_sequence != device_group->outgoing_sequence) { // If we haven't receive an ack from this member in DGR_MEMBER_TIMEOUT ms, assume // they're offline and remove them from the group. if ((long)(now - device_group->member_timeout_time) >= 0) { *flink = device_group_member->flink; free(device_group_member); AddLog(LOG_LEVEL_DEBUG, PSTR("DGR: Member %s removed"), IPAddressToString(device_group_member->ip_address)); continue; } // Otherwise, unicast the last message directly to this member. SendReceiveDeviceGroupMessage(device_group, device_group_member, device_group->message, device_group->message_length, false); device_group_member->unicast_count++; acked = false; } flink = &device_group_member->flink; } // If we've received an ack to the last message from all members, clear the ack check // time and zero-out the message length. if (acked) { device_group->next_ack_check_time = 0; device_group->message_length = 0; // Let _SendDeviceGroupMessage know we're done with this update } // If there are still members we haven't received an ack from, set the next ack check // time. We start at 200ms and double the interval each pass with a maximum interval of // 5 seconds. else { device_group->ack_check_interval *= 2; if (device_group->ack_check_interval > 5000) device_group->ack_check_interval = 5000; device_group->next_ack_check_time = now + device_group->ack_check_interval; } } } if (device_group->next_ack_check_time < next_check_time) next_check_time = device_group->next_ack_check_time; } // If it's time to send a multicast announcement for this group, send it. This is to // announce ourself to any members that have somehow not heard about us. We send it at the // announcement interval plus a random number of milliseconds so that even if all the devices // booted at the same time, they don't all multicast their announcements at the same time. #ifdef DEVICE_GROUPS_DEBUG AddLog(LOG_LEVEL_DEBUG, PSTR("DGR: next_announcement_time=%u, now=%u"), device_group->next_announcement_time, now); #endif // DEVICE_GROUPS_DEBUG if ((long)(now - device_group->next_announcement_time) >= 0) { SendReceiveDeviceGroupMessage(device_group, nullptr, device_group->message, BeginDeviceGroupMessage(device_group, DGR_FLAG_ANNOUNCEMENT, true) - device_group->message, false); device_group->next_announcement_time = now + DGR_ANNOUNCEMENT_INTERVAL + random(10000); } if (device_group->next_announcement_time < next_check_time) next_check_time = device_group->next_announcement_time; } } } #endif // USE_DEVICE_GROUPS