#ifdef USE_ARDUINO #include "dsmr.h" #include "esphome/core/log.h" #include #include #include namespace esphome { namespace dsmr { static const char *const TAG = "dsmr"; void Dsmr::setup() { this->telegram_ = new char[this->max_telegram_len_]; // NOLINT if (this->request_pin_ != nullptr) { this->request_pin_->setup(); } } void Dsmr::loop() { if (this->ready_to_request_data_()) { if (this->decryption_key_.empty()) { this->receive_telegram_(); } else { this->receive_encrypted_(); } } } bool Dsmr::ready_to_request_data_() { // When using a request pin, then wait for the next request interval. if (this->request_pin_ != nullptr) { if (!this->requesting_data_ && this->request_interval_reached_()) { this->start_requesting_data_(); } } // Otherwise, sink serial data until next request interval. else { if (this->request_interval_reached_()) { this->start_requesting_data_(); } if (!this->requesting_data_) { while (this->available()) { this->read(); } } } return this->requesting_data_; } bool Dsmr::request_interval_reached_() { if (this->last_request_time_ == 0) { return true; } return millis() - this->last_request_time_ > this->request_interval_; } bool Dsmr::available_within_timeout_() { uint8_t tries = READ_TIMEOUT_MS / 5; while (tries--) { delay(5); if (this->available()) { return true; } } return false; } void Dsmr::start_requesting_data_() { if (!this->requesting_data_) { if (this->request_pin_ != nullptr) { ESP_LOGV(TAG, "Start requesting data from P1 port"); this->request_pin_->digital_write(true); } else { ESP_LOGV(TAG, "Start reading data from P1 port"); } this->requesting_data_ = true; this->last_request_time_ = millis(); } } void Dsmr::stop_requesting_data_() { if (this->requesting_data_) { if (this->request_pin_ != nullptr) { ESP_LOGV(TAG, "Stop requesting data from P1 port"); this->request_pin_->digital_write(false); } else { ESP_LOGV(TAG, "Stop reading data from P1 port"); } while (this->available()) { this->read(); } this->requesting_data_ = false; } } void Dsmr::receive_telegram_() { while (true) { if (!this->available()) { if (!this->header_found_ || !this->available_within_timeout_()) { return; } } const char c = this->read(); // Find a new telegram header, i.e. forward slash. if (c == '/') { ESP_LOGV(TAG, "Header of telegram found"); this->header_found_ = true; this->footer_found_ = false; this->telegram_len_ = 0; } if (!this->header_found_) continue; // Check for buffer overflow. if (this->telegram_len_ >= this->max_telegram_len_) { this->header_found_ = false; this->footer_found_ = false; ESP_LOGE(TAG, "Error: telegram larger than buffer (%d bytes)", this->max_telegram_len_); return; } // Some v2.2 or v3 meters will send a new value which starts with '(' // in a new line, while the value belongs to the previous ObisId. For // proper parsing, remove these new line characters. if (c == '(') { while (true) { auto previous_char = this->telegram_[this->telegram_len_ - 1]; if (previous_char == '\n' || previous_char == '\r') { this->telegram_len_--; } else { break; } } } // Store the byte in the buffer. this->telegram_[this->telegram_len_] = c; this->telegram_len_++; // Check for a footer, i.e. exlamation mark, followed by a hex checksum. if (c == '!') { ESP_LOGV(TAG, "Footer of telegram found"); this->footer_found_ = true; continue; } // Check for the end of the hex checksum, i.e. a newline. if (this->footer_found_ && c == '\n') { // Parse the telegram and publish sensor values. this->parse_telegram(); this->header_found_ = false; return; } } } void Dsmr::receive_encrypted_() { this->encrypted_telegram_len_ = 0; size_t packet_size = 0; while (true) { if (!this->available()) { if (!this->header_found_) { return; } if (!this->available_within_timeout_()) { ESP_LOGW(TAG, "Timeout while reading data for encrypted telegram"); return; } } const char c = this->read(); // Find a new telegram start byte. if (!this->header_found_) { if ((uint8_t) c != 0xDB) { continue; } ESP_LOGV(TAG, "Start byte 0xDB of encrypted telegram found"); this->header_found_ = true; } // Check for buffer overflow. if (this->encrypted_telegram_len_ >= this->max_telegram_len_) { this->header_found_ = false; ESP_LOGE(TAG, "Error: encrypted telegram larger than buffer (%d bytes)", this->max_telegram_len_); return; } this->encrypted_telegram_[this->encrypted_telegram_len_++] = c; if (packet_size == 0 && this->encrypted_telegram_len_ > 20) { // Complete header + data bytes packet_size = 13 + (this->encrypted_telegram_[11] << 8 | this->encrypted_telegram_[12]); ESP_LOGV(TAG, "Encrypted telegram size: %d bytes", packet_size); } if (this->encrypted_telegram_len_ == packet_size && packet_size > 0) { ESP_LOGV(TAG, "End of encrypted telegram found"); GCM *gcmaes128{new GCM()}; gcmaes128->setKey(this->decryption_key_.data(), gcmaes128->keySize()); // the iv is 8 bytes of the system title + 4 bytes frame counter // system title is at byte 2 and frame counter at byte 15 for (int i = 10; i < 14; i++) this->encrypted_telegram_[i] = this->encrypted_telegram_[i + 4]; constexpr uint16_t iv_size{12}; gcmaes128->setIV(&this->encrypted_telegram_[2], iv_size); gcmaes128->decrypt(reinterpret_cast(this->telegram_), // the ciphertext start at byte 18 &this->encrypted_telegram_[18], // cipher size this->encrypted_telegram_len_ - 17); delete gcmaes128; // NOLINT(cppcoreguidelines-owning-memory) this->telegram_len_ = strnlen(this->telegram_, this->max_telegram_len_); ESP_LOGV(TAG, "Decrypted telegram size: %d bytes", this->telegram_len_); ESP_LOGVV(TAG, "Decrypted telegram: %s", this->telegram_); this->parse_telegram(); this->header_found_ = false; this->telegram_len_ = 0; return; } } } bool Dsmr::parse_telegram() { MyData data; ESP_LOGV(TAG, "Trying to parse telegram"); this->stop_requesting_data_(); ::dsmr::ParseResult res = ::dsmr::P1Parser::parse(&data, this->telegram_, this->telegram_len_, false, this->crc_check_); // Parse telegram according to data definition. Ignore unknown values. if (res.err) { // Parsing error, show it auto err_str = res.fullError(this->telegram_, this->telegram_ + this->telegram_len_); ESP_LOGE(TAG, "%s", err_str.c_str()); return false; } else { this->status_clear_warning(); this->publish_sensors(data); return true; } } void Dsmr::dump_config() { ESP_LOGCONFIG(TAG, "DSMR:"); ESP_LOGCONFIG(TAG, " Max telegram length: %d", this->max_telegram_len_); if (this->request_pin_ != nullptr) { LOG_PIN(" Request Pin: ", this->request_pin_); } if (this->request_interval_ > 0) { ESP_LOGCONFIG(TAG, " Request Interval: %.1fs", this->request_interval_ / 1e3f); } #define DSMR_LOG_SENSOR(s) LOG_SENSOR(" ", #s, this->s_##s##_); DSMR_SENSOR_LIST(DSMR_LOG_SENSOR, ) #define DSMR_LOG_TEXT_SENSOR(s) LOG_TEXT_SENSOR(" ", #s, this->s_##s##_); DSMR_TEXT_SENSOR_LIST(DSMR_LOG_TEXT_SENSOR, ) } void Dsmr::set_decryption_key(const std::string &decryption_key) { if (decryption_key.length() == 0) { ESP_LOGI(TAG, "Disabling decryption"); this->decryption_key_.clear(); if (this->encrypted_telegram_ != nullptr) { delete[] this->encrypted_telegram_; this->encrypted_telegram_ = nullptr; } return; } if (decryption_key.length() != 32) { ESP_LOGE(TAG, "Error, decryption key must be 32 character long"); return; } this->decryption_key_.clear(); ESP_LOGI(TAG, "Decryption key is set"); // Verbose level prints decryption key ESP_LOGV(TAG, "Using decryption key: %s", decryption_key.c_str()); char temp[3] = {0}; for (int i = 0; i < 16; i++) { strncpy(temp, &(decryption_key.c_str()[i * 2]), 2); this->decryption_key_.push_back(std::strtoul(temp, nullptr, 16)); } if (this->encrypted_telegram_ == nullptr) { this->encrypted_telegram_ = new uint8_t[this->max_telegram_len_]; // NOLINT } } void Dsmr::set_max_telegram_length(size_t length) { max_telegram_len_ = length; } } // namespace dsmr } // namespace esphome #endif // USE_ARDUINO