Configura un nuovo dispositivo per testare le applicazioni V1 su V2 (Greengrass nucleus lite) - AWS IoT Greengrass
Passaggio 1: installa Greengrass nucleus lite su un nuovo dispositivoFase 2: Creare e distribuire componenti generici per migrare le funzioni AWS IoT Greengrass V1 Lambda

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Configura un nuovo dispositivo per testare le applicazioni V1 su V2 (Greengrass nucleus lite)

Configura un nuovo dispositivo con Greengrass nucleus lite per testare i componenti generici che crei per migrare le tue AWS IoT Greengrass V1 applicazioni alla V2. Greengrass nucleus lite è un runtime leggero ottimizzato per dispositivi con risorse limitate. È possibile utilizzare questo dispositivo per sviluppare e testare componenti Greengrass personalizzati che eseguono processi nativi. Dopo aver testato le applicazioni su un dispositivo Greengrass nucleus lite, è possibile distribuire i componenti V2 su altri dispositivi che eseguono Greengrass nucleus lite o aggiornare i dispositivi core V1 esistenti alla V2.

Passaggio 1: installa Greengrass nucleus lite su un nuovo dispositivo

Installa Greengrass nucleus lite su un nuovo dispositivo. Segui la guida all'installazione di Greengrass nucleus lite per configurare un dispositivo.

Nota

Greengrass nucleus lite non supporta attualmente il servizio shadow locale, i dispositivi client o i connettori. Assicurati che le tue applicazioni V1 non si basino su queste funzionalità prima di procedere con questa guida.

Fase 2: Creare e distribuire componenti generici per migrare le funzioni AWS IoT Greengrass V1 Lambda

Per replicare la funzionalità delle funzioni AWS IoT Greengrass V1 Lambda su Greengrass nucleus lite, è necessario convertirle in componenti generici. Ciò comporta la riscrittura del codice della funzione Lambda per utilizzare SDK per dispositivi AWS IoT V2 AWS IoT Greengrass o Component SDK anziché Core SDK. AWS IoT Greengrass

La tabella seguente elenca gli esempi di componenti SDKs utilizzati negli esempi di componenti V2 di questa guida:

SDK Versione minima
SDK per dispositivi AWS IoT per Python v2 v1.11.3
SDK per dispositivi AWS IoT per Java v2 v1.9.3
SDK per dispositivi AWS IoT per v2 JavaScript v1.12.0
AWS IoT Greengrass Component SDK (C/C++) (attualmente in anteprima) v0.4.0

Gli esempi seguenti mostrano le funzioni Lambda che utilizzano AWS IoT Greengrass V1 Core SDK e i relativi componenti generici equivalenti, con codice componente, ricette e istruzioni di compilazione in più linguaggi di programmazione per due scenari principali:

  • Comunicazione locale: componenti che comunicano con altri componenti sullo stesso dispositivo tramite pub/sub locale

  • Comunicazione cloud: componenti che comunicano con AWS IoT Core o altri servizi AWS

Scenario 1: Comunicazione locale (editore → processore → abbonato)

Questo scenario dimostra la conversione di una funzione Lambda V1 che utilizza la comunicazione pub/sub locale in un componente generico V2.

Architettura dell'applicazione

Questo esempio include tre componenti:

  • L'editore Lambda pubblica i dati sulla temperatura

  • Il processore Lambda riceve i dati e li elabora

  • Il processore Lambda pubblica il risultato elaborato all'abbonato Lambda

L'esempio di codice riportato di seguito si concentra sul processore Lambda, che dimostra sia la sottoscrizione che la pubblicazione di messaggi per la comunicazione locale.

Abbonamenti di gruppo V1

In AWS IoT Greengrass V1, i seguenti abbonamenti di gruppo abilitano la comunicazione tra le funzioni Lambda:

Abbonamento 1: editore → processore

  • Fonte: Lambda (editore)

  • Obiettivo: Lambda (processore)

  • Argomento: sensori/temperatura

Abbonamento 2: processore → abbonato

  • Fonte: Lambda (processore)

  • Target: Lambda (abbonato)

  • Argomento: lambda/alerts

Funzione Lambda del processore (V1)

Python
import greengrasssdk
import json

iot_client = greengrasssdk.client('iot-data')

def lambda_handler(event, context):
    """
    Receives temperature from publisher Lambda,
    processes it, and forwards to subscriber Lambda
    """
    # Receive from publisher Lambda.
    sensor_id = event['sensor_id']
    temperature = event['temperature']
    
    print(f"Received from sensor {sensor_id}: {temperature}°F")
    
    # Process: Check if temperature is high.
    if temperature > 80:
        alert_data = {
            'sensor_id': sensor_id,
            'temperature': temperature,
            'alert': 'HIGH_TEMPERATURE'
        }
        
        # Publish to another Lambda using greengrasssdk.
        iot_client.publish(
            topic='lambda/alerts',
            payload=json.dumps(alert_data)
        )
        
        print(f"Alert sent to subscriber Lambda")
    
    return {'statusCode': 200}
Java
import com.amazonaws.greengrass.javasdk.IotDataClient;
import com.amazonaws.greengrass.javasdk.model.PublishRequest;
import com.amazonaws.services.lambda.runtime.Context;
import com.google.gson.Gson;
import java.nio.ByteBuffer;
import java.nio.charset.StandardCharsets;
import java.util.HashMap;
import java.util.Map;

public class TemperatureProcessorLambda {
    private static final Gson gson = new Gson();
    private final IotDataClient iotDataClient;

    public TemperatureProcessorLambda() {
        this.iotDataClient = new IotDataClient();
    }

    public String handleRequest(Map<String, Object> event, Context context) {
        /*
         * Receives temperature from publisher Lambda,
         * processes it, and forwards to subscriber Lambda
         */

        // Receive from publisher Lambda.
        String sensorId = (String) event.get("sensor_id");
        Number temp = (Number) event.get("temperature");
        int temperature = temp.intValue();

        System.out.println("Received from sensor " + sensorId + ": " + temperature + "°F");

        // Process: Check if temperature is high.
        if (temperature > 80) {
            Map<String, Object> alertData = new HashMap<>();
            alertData.put("sensor_id", sensorId);
            alertData.put("temperature", temperature);
            alertData.put("alert", "HIGH_TEMPERATURE");

            // Publish to another Lambda using greengrasssdk.
            String payload = gson.toJson(alertData);
            PublishRequest publishRequest = new PublishRequest()
                .withTopic("lambda/alerts")
                .withPayload(ByteBuffer.wrap(payload.getBytes(StandardCharsets.UTF_8)));

            iotDataClient.publish(publishRequest);

            System.out.println("Alert sent to subscriber Lambda");
        }

        return "Success";
    }
}
JavaScript
const greengrasssdk = require('aws-greengrass-core-sdk');

const iotClient = new greengrasssdk.IotData();

/**
 * Greengrass v1 Lambda function
 * Receives temperature from publisher Lambda,
 * processes it, and forwards to subscriber Lambda
 */
exports.handler = function(event, context) {
    // Receive from publisher Lambda.
    const sensorId = event.sensor_id;
    const temperature = event.temperature;
    
    console.log(`Received from sensor ${sensorId}: ${temperature}°F`);
    
    // Process: Check if temperature is high.
    if (temperature > 80) {
        const alertData = {
            sensor_id: sensorId,
            temperature: temperature,
            alert: 'HIGH_TEMPERATURE'
        };
        
        // Publish to another Lambda using greengrasssdk.
        const params = {
            topic: 'lambda/alerts',
            payload: JSON.stringify(alertData)
        };
        
        iotClient.publish(params, (err) => {
            if (err) {
                console.error('Error publishing alert:', err);
                context.fail(err);
            } else {
                console.log('Alert sent to subscriber Lambda');
                context.succeed('Success');
            }
        });
    } else {
        context.succeed('Success');
    }
};
C
#include <aws/greengrass/greengrasssdk.h>
#include <stdio.h>
#include <string.h>
#include <jansson.h>  // For JSON parsing.

static aws_greengrass_iot_data_client *iot_client = NULL;

void on_message_received(const char *topic, const uint8_t *payload, size_t payload_len, void *user_data) {
    // Parse the incoming message.
    char *payload_str = strndup((char *)payload, payload_len);
    json_error_t error;
    json_t *event = json_loads(payload_str, 0, &error);
    free(payload_str);
    
    if (!event) {
        fprintf(stderr, "Error parsing JSON: %s\n", error.text);
        return;
    }
    
    // Receive from publisher Lambda.
    json_t *sensor_id_obj = json_object_get(event, "sensor_id");
    json_t *temperature_obj = json_object_get(event, "temperature");
    
    const char *sensor_id = json_string_value(sensor_id_obj);
    int temperature = json_integer_value(temperature_obj);
    
    printf("Received from sensor %s: %d°F\n", sensor_id, temperature);
    
    // Process: Check if temperature is high.
    if (temperature > 80) {
        // Create alert data.
        json_t *alert_data = json_object();
        json_object_set_new(alert_data, "sensor_id", json_string(sensor_id));
        json_object_set_new(alert_data, "temperature", json_integer(temperature));
        json_object_set_new(alert_data, "alert", json_string("HIGH_TEMPERATURE"));
        
        // Convert to JSON string.
        char *alert_payload = json_dumps(alert_data, JSON_COMPACT);
        
        // Publish to another Lambda using greengrasssdk.
        aws_greengrass_publish_params params = {
            .topic = "lambda/alerts",
            .payload = (uint8_t *)alert_payload,
            .payload_len = strlen(alert_payload)
        };
        
        aws_greengrass_iot_data_publish(iot_client, &params);
        
        printf("Alert sent to subscriber Lambda\n");
        
        free(alert_payload);
        json_decref(alert_data);
    }
    
    json_decref(event);
}

int main(int argc, char *argv[]) {
    // Initialize Greengrass SDK.
    iot_client = aws_greengrass_iot_data_client_new();
    
    // Subscribe to temperature sensor topic.
    aws_greengrass_subscribe_params subscribe_params = {
        .topic = "sensors/temperature",
        .callback = on_message_received,
        .user_data = NULL
    };
    
    aws_greengrass_iot_data_subscribe(iot_client, &subscribe_params);
    
    printf("Temperature Processor Lambda started\n");
    printf("Subscribed to sensors/temperature\n");
    printf("Waiting for sensor data...\n");
    
    // Keep the Lambda running.
    while (1) {
        sleep(1);
    }
    
    return 0;
}
C++
#include <aws/greengrass/greengrasssdk.h>
#include <iostream>
#include <string>
#include <memory>
#include <jansson.h> // For JSON parsing.
#include <unistd.h>

class TemperatureProcessor {
private:
    std::unique_ptr<aws_greengrass_iot_data_client, 
                    decltype(&aws_greengrass_iot_data_client_destroy)> iot_client;
    
    static void message_callback_wrapper(const char *topic, 
                                        const uint8_t *payload, 
                                        size_t payload_len, 
                                        void *user_data) {
        auto* processor = static_cast<TemperatureProcessor*>(user_data);
        processor->on_message_received(topic, payload, payload_len);
    }

public:
    TemperatureProcessor() 
        : iot_client(aws_greengrass_iot_data_client_new(), 
                     aws_greengrass_iot_data_client_destroy) {
        if (!iot_client) {
            throw std::runtime_error("Failed to create Greengrass IoT client");
        }
    }

    void on_message_received(const char *topic, 
                            const uint8_t *payload, 
                            size_t payload_len) {
        // Parse the incoming message.
        std::string payload_str(reinterpret_cast<const char*>(payload), payload_len);
        
        json_error_t error;
        json_t *event = json_loads(payload_str.c_str(), 0, &error);
        
        if (!event) {
            std::cerr << "Error parsing JSON: " << error.text << std::endl;
            return;
        }

        json_t *sensor_id_obj = json_object_get(event, "sensor_id");
        json_t *temperature_obj = json_object_get(event, "temperature");
        
        const char *sensor_id = json_string_value(sensor_id_obj);
        int temperature = json_integer_value(temperature_obj);
        
        std::cout << "Received from sensor " << sensor_id 
                  << ": " << temperature << "°F" << std::endl;

        if (temperature > 80) {
            send_alert(sensor_id, temperature);
        }

        json_decref(event);
    }

    void send_alert(const char *sensor_id, int temperature) {
        // Create alert data.
        json_t *alert_data = json_object();
        json_object_set_new(alert_data, "sensor_id", json_string(sensor_id));
        json_object_set_new(alert_data, "temperature", json_integer(temperature));
        json_object_set_new(alert_data, "alert", json_string("HIGH_TEMPERATURE"));

        // Convert to JSON string.
        char *alert_payload = json_dumps(alert_data, JSON_COMPACT);

        // Publish to another Lambda using greengrasssdk.
        aws_greengrass_publish_params params = {
            .topic = "lambda/alerts",
            .payload = reinterpret_cast<uint8_t*>(alert_payload),
            .payload_len = strlen(alert_payload)
        };
        
        aws_greengrass_iot_data_publish(iot_client.get(), &params);
        
        std::cout << "Alert sent to subscriber Lambda" << std::endl;

        free(alert_payload);
        json_decref(alert_data);
    }

    void subscribe_to_topic(const std::string& topic) {
        aws_greengrass_subscribe_params subscribe_params = {
            .topic = topic.c_str(),
            .callback = message_callback_wrapper,
            .user_data = this
        };
        
        aws_greengrass_iot_data_subscribe(iot_client.get(), &subscribe_params);
        
        std::cout << "Temperature Processor Lambda started" << std::endl;
        std::cout << "Subscribed to " << topic << std::endl;
        std::cout << "Waiting for sensor data..." << std::endl;
    }

    void run() {
        // Keep the Lambda running.
        while (true) {
            sleep(1);
        }
    }
};

int main(int argc, char *argv[]) {
    try {
        TemperatureProcessor processor;
        processor.subscribe_to_topic("sensors/temperature");
        processor.run();
    } catch (const std::exception& e) {
        std::cerr << "Error: " << e.what() << std::endl;
        return 1;
    }
    
    return 0;
}

Componente generico (V2)

Per ottenere la stessa funzionalità in AWS IoT Greengrass V2, crea un componente generico con quanto segue:

1. Codice del componente
Python

Prerequisiti: prima di utilizzare questo codice componente, installa e verifica il SDK per dispositivi AWS IoT for Python sul tuo dispositivo Greengrass:

# Install the SDK
pip3 install awsiotsdk

# Verify installation
python3 -c "import awsiot.greengrasscoreipc.clientv2; print('SDK installed successfully')"

Se riscontrate conflitti di dipendenza durante l'installazione, provate a installare una versione specifica di. SDK per dispositivi AWS IoT

Se il comando di verifica stampa «SDK installato correttamente», sei pronto per utilizzare il codice del componente:

from awsiot.greengrasscoreipc.clientv2 import GreengrassCoreIPCClientV2
from awsiot.greengrasscoreipc.model import (
    PublishMessage,
    JsonMessage
)
import time

ipc_client = GreengrassCoreIPCClientV2()

def on_sensor_data(event):
    """
    Receives temperature from sensor publisher component,
    processes it, and forwards to alert component
    """
    try:
        # Receive from publisher component.
        data = event.json_message.message
        sensor_id = data['sensor_id']
        temperature = data['temperature']
        
        print(f"Received from sensor {sensor_id}: {temperature}°F")
        
        # Process: Check if temperature is high.
        if temperature > 80:
            alert_data = {
                'sensor_id': sensor_id,
                'temperature': temperature,
                'alert': 'HIGH_TEMPERATURE'
            }
            
            # Publish to another component (AlertHandler).
            ipc_client.publish_to_topic(
                topic='component/alerts',
                publish_message=PublishMessage(
                    json_message=JsonMessage(message=alert_data)
                )
            )
            
            print(f"Alert sent to AlertHandler component")
    
    except Exception as e:
        print(f"Error processing sensor data: {e}")

def main():
    print("Temperature Processor component starting...")
    
    # Subscribe to sensor data from publisher component.
    ipc_client.subscribe_to_topic(
        topic='sensors/temperature',
        on_stream_event=on_sensor_data
    )
    
    print("Subscribed to sensors/temperature")
    print("Waiting for sensor data...")
    
    # Keep running.
    while True:
        time.sleep(1)

if __name__ == '__main__':
    main()
Java
import software.amazon.awssdk.aws.greengrass.GreengrassCoreIPCClientV2;
import software.amazon.awssdk.aws.greengrass.model.PublishMessage;
import software.amazon.awssdk.aws.greengrass.model.PublishToTopicRequest;
import software.amazon.awssdk.aws.greengrass.model.JsonMessage;
import software.amazon.awssdk.aws.greengrass.model.SubscribeToTopicRequest;
import software.amazon.awssdk.aws.greengrass.model.SubscriptionResponseMessage;
import java.util.HashMap;
import java.util.Map;
import java.util.Optional;

public class TemperatureProcessor {
    private static GreengrassCoreIPCClientV2 ipcClient;

    public static void main(String[] args) {
        System.out.println("Temperature Processor component starting...");

        try (GreengrassCoreIPCClientV2 client = GreengrassCoreIPCClientV2.builder().build()) {
            ipcClient = client;

            SubscribeToTopicRequest subscribeRequest = new SubscribeToTopicRequest()
                .withTopic("sensors/temperature");

            ipcClient.subscribeToTopic(
                subscribeRequest, 
                TemperatureProcessor::onSensorData,
                Optional.empty(),
                Optional.empty()
            );

            System.out.println("Subscribed to sensors/temperature");
            System.out.println("Waiting for sensor data...");

            while (true) {
                Thread.sleep(1000);
            }
        } catch (Exception e) {
            System.err.println("Error: " + e.getMessage());
            e.printStackTrace();
        }
    }

    public static void onSensorData(SubscriptionResponseMessage message) {
        try {
            Map<String, Object> data = message.getJsonMessage().getMessage();
            String sensorId = (String) data.get("sensor_id");
            Number temp = (Number) data.get("temperature");
            int temperature = temp.intValue();

            System.out.println("Received from sensor " + sensorId + ": " + temperature + "F");

            if (temperature > 80) {
                Map<String, Object> alertData = new HashMap<>();
                alertData.put("sensor_id", sensorId);
                alertData.put("temperature", temperature);
                alertData.put("alert", "HIGH_TEMPERATURE");

                JsonMessage jsonMessage = new JsonMessage().withMessage(alertData);
                PublishMessage publishMessage = new PublishMessage().withJsonMessage(jsonMessage);
                PublishToTopicRequest publishRequest = new PublishToTopicRequest()
                    .withTopic("component/alerts")
                    .withPublishMessage(publishMessage);

                ipcClient.publishToTopic(publishRequest);
                System.out.println("Alert sent to AlertHandler component");
            }
        } catch (Exception e) {
            System.err.println("Error processing sensor data: " + e.getMessage());
        }
    }
}
JavaScript
const greengrasscoreipc = require('aws-iot-device-sdk-v2').greengrasscoreipc;

class TemperatureProcessor {
    constructor() {
        this.ipcClient = null;
    }

    async start() {
        console.log('Temperature Processor component starting...');
        
        try {
            this.ipcClient = greengrasscoreipc.createClient();
            await this.ipcClient.connect();
            
            const subscribeRequest = {
                topic: 'sensors/temperature'
            };

            const streamingOperation = this.ipcClient.subscribeToTopic(subscribeRequest);
            
            streamingOperation.on('message', (message) => {
                this.onSensorData(message);
            });
            
            streamingOperation.on('streamError', (error) => {
                console.error('Stream error:', error);
            });
            
            streamingOperation.on('ended', () => {
                console.log('Subscription stream ended');
            });
            
            await streamingOperation.activate();
            
            console.log('Subscribed to sensors/temperature');
            console.log('Waiting for sensor data...');
            
        } catch (error) {
            console.error('Error starting component:', error);
            process.exit(1);
        }
    }

    async onSensorData(message) {
        try {
            const data = message.jsonMessage.message;
            
            const sensorId = data.sensor_id;
            const temperature = data.temperature;
            
            console.log(`Received from sensor ${sensorId}: ${temperature}°F`);
            
            if (temperature > 80) {
                const alertData = {
                    sensor_id: sensorId,
                    temperature: temperature,
                    alert: 'HIGH_TEMPERATURE'
                };
                
                const publishRequest = {
                    topic: 'component/alerts',
                    publishMessage: {
                        jsonMessage: {
                            message: alertData
                        }
                    }
                };
                
                await this.ipcClient.publishToTopic(publishRequest);
                console.log('Alert sent to AlertHandler component');
            }
            
        } catch (error) {
            console.error('Error processing sensor data:', error);
        }
    }
}

// Start the component.
const processor = new TemperatureProcessor();
processor.start();
C
#include <gg/buffer.h>
#include <gg/error.h>
#include <gg/ipc/client.h>
#include <gg/map.h>
#include <gg/object.h>
#include <gg/sdk.h>
#include <unistd.h>
#include <stdbool.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <pthread.h>

#define SUBSCRIBE_TOPIC "sensors/temperature"
#define PUBLISH_TOPIC "component/alerts"

typedef struct {
    char sensor_id[64];
    int64_t temperature;
} AlertData;

static pthread_mutex_t alert_mutex = PTHREAD_MUTEX_INITIALIZER;
static pthread_cond_t alert_cond = PTHREAD_COND_INITIALIZER;
static AlertData pending_alert;
static bool has_pending_alert = false;

static void *alert_publisher_thread(void *arg) {
    (void) arg;
    
    while (true) {
        pthread_mutex_lock(&alert_mutex);
        while (!has_pending_alert) {
            pthread_cond_wait(&alert_cond, &alert_mutex);
        }
        
        AlertData alert = pending_alert;
        has_pending_alert = false;
        pthread_mutex_unlock(&alert_mutex);
        
        GgBuffer sensor_id_buf = { .data = (uint8_t *)alert.sensor_id, .len = strlen(alert.sensor_id) };
        GgMap payload = GG_MAP(
            gg_kv(GG_STR("sensor_id"), gg_obj_buf(sensor_id_buf)),
            gg_kv(GG_STR("temperature"), gg_obj_i64(alert.temperature)),
            gg_kv(GG_STR("alert"), gg_obj_buf(GG_STR("HIGH_TEMPERATURE")))
        );
        
        GgError ret = ggipc_publish_to_topic_json(GG_STR(PUBLISH_TOPIC), payload);
        
        if (ret != GG_ERR_OK) {
            fprintf(stderr, "Failed to publish alert\n");
        } else {
            printf("Alert sent to AlertHandler component\n");
        }
    }
    
    return NULL;
}

static void on_sensor_data(
    void *ctx, GgBuffer topic, GgObject payload, GgIpcSubscriptionHandle handle
) {
    (void) ctx;
    (void) topic;
    (void) handle;
    
    if (gg_obj_type(payload) != GG_TYPE_MAP) {
        fprintf(stderr, "Expected JSON message\n");
        return;
    }
    
    GgMap map = gg_obj_into_map(payload);
    
    GgObject *sensor_id_obj;
    if (!gg_map_get(map, GG_STR("sensor_id"), &sensor_id_obj)) {
        fprintf(stderr, "Missing sensor_id field\n");
        return;
    }
    GgBuffer sensor_id = gg_obj_into_buf(*sensor_id_obj);
    
    GgObject *temperature_obj;
    if (!gg_map_get(map, GG_STR("temperature"), &temperature_obj)) {
        fprintf(stderr, "Missing temperature field\n");
        return;
    }
    int64_t temperature = gg_obj_into_i64(*temperature_obj);
    
    printf("Received from sensor %.*s: %lld°F\n", 
           (int)sensor_id.len, sensor_id.data, (long long)temperature);
    
    if (temperature > 80) {
        pthread_mutex_lock(&alert_mutex);
        snprintf(pending_alert.sensor_id, sizeof(pending_alert.sensor_id),
                 "%.*s", (int)sensor_id.len, sensor_id.data);
        pending_alert.temperature = temperature;
        has_pending_alert = true;
        pthread_cond_signal(&alert_cond);
        pthread_mutex_unlock(&alert_mutex);
    }
}

int main(void) {
    setvbuf(stdout, NULL, _IONBF, 0);
    printf("Temperature Processor component starting...\n");
    
    gg_sdk_init();
    
    GgError ret = ggipc_connect();
    if (ret != GG_ERR_OK) {
        fprintf(stderr, "Failed to connect to Greengrass nucleus\n");
        exit(1);
    }
    printf("Connected to Greengrass IPC\n");
    
    // Start alert publisher thread.
    pthread_t alert_thread;
    if (pthread_create(&alert_thread, NULL, alert_publisher_thread, NULL) != 0) {
        fprintf(stderr, "Failed to create alert publisher thread\n");
        exit(1);
    }
    
    GgIpcSubscriptionHandle handle;
    ret = ggipc_subscribe_to_topic(
        GG_STR(SUBSCRIBE_TOPIC),
        &on_sensor_data,
        NULL,
        &handle
    );
    
    if (ret != GG_ERR_OK) {
        fprintf(stderr, "Failed to subscribe to topic\n");
        exit(1);
    }
    
    printf("Subscribed to %s\n", SUBSCRIBE_TOPIC);
    printf("Waiting for sensor data...\n");
    
    // Keep running.
    while (true) {
        sleep(1);
    }
    
    return 0;
}
C++
#include <gg/ipc/client.hpp>
#include <gg/buffer.hpp>
#include <gg/object.hpp>
#include <gg/types.hpp>

#include <chrono>
#include <condition_variable>
#include <iostream>
#include <mutex>
#include <string>
#include <string_view>
#include <thread>

struct AlertData {
    std::string sensor_id;
    int64_t temperature;
};

static std::mutex alert_mutex;
static std::condition_variable alert_cv;
static AlertData pending_alert;
static bool has_pending_alert = false;

void alert_publisher_thread() {
    auto& client = gg::ipc::Client::get();
    
    while (true) {
        std::unique_lock<std::mutex> lock(alert_mutex);
        alert_cv.wait(lock, [] { return has_pending_alert; });
        
        AlertData alert = pending_alert;
        has_pending_alert = false;
        lock.unlock();
        
        // Create alert payload as JSON string.
        std::string json_payload = "{\"sensor_id\":\"" + alert.sensor_id + 
                                  "\",\"temperature\":" + std::to_string(alert.temperature) + 
                                  ",\"alert\":\"HIGH_TEMPERATURE\"}";
        
        // Convert to Buffer and publish.
        gg::Buffer buffer(json_payload);
        auto error = client.publish_to_topic("component/alerts", buffer);
        
        if (error) {
            std::cerr << "Failed to publish alert\n";
        } else {
            std::cout << "Alert sent to AlertHandler component\n";
        }
    }
}

class SensorCallback : public gg::ipc::LocalTopicCallback {
    void operator()(
        std::string_view topic,
        gg::Object payload,
        gg::ipc::Subscription& handle
    ) override {
        (void) topic;
        (void) handle;
        
        // Payload is a Buffer containing JSON string.
        if (payload.index() != GG_TYPE_BUF) {
            std::cerr << "Expected Buffer message\n";
            return;
        }
        
        // Extract buffer using gg::get.
        auto buffer = gg::get<std::span<uint8_t>>(payload);
        std::string json_str(reinterpret_cast<const char*>(buffer.data()), buffer.size());
        
        // Simple JSON parsing for demo.
        std::string sensor_id = "sensor1"; 
        int64_t temperature = 0;
        
        // Extract temperature (simple string search).
        size_t temp_pos = json_str.find("\"temperature\":");
        if (temp_pos != std::string::npos) {
            temp_pos += 14; // Skip "temperature".
            size_t end_pos = json_str.find_first_of(",}", temp_pos);
            if (end_pos != std::string::npos) {
                temperature = std::stoll(json_str.substr(temp_pos, end_pos - temp_pos));
            }
        }
        
        std::cout << "Received from sensor " << sensor_id << ": " 
                  << temperature << "°F\n";
        
        if (temperature > 80) {
            std::lock_guard<std::mutex> lock(alert_mutex);
            pending_alert = {sensor_id, temperature};
            has_pending_alert = true;
            alert_cv.notify_one();
        }
    }
};

int main() {
    // Disable stdout buffering for real-time logging.
    std::cout.setf(std::ios::unitbuf);
    
    std::cout << "Temperature Processor component starting..." << std::endl;
    
    auto& client = gg::ipc::Client::get();
    std::cout << "Got client instance" << std::endl;
    
    auto error = client.connect();
    std::cout << "Connect returned, error code: " << error.value() << std::endl;
    
    if (error) {
        std::cerr << "Failed to connect to Greengrass nucleus: " << error.message() << std::endl;
        return 1;
    }
    
    std::cout << "Connected to Greengrass IPC" << std::endl;
    
    // Start alert publisher thread.
    std::thread alert_thread(alert_publisher_thread);
    alert_thread.detach();
    
    // Handler must be static lifetime if subscription handle is not held.
    static SensorCallback handler;
    error = client.subscribe_to_topic("sensors/temperature", handler);
    
    if (error) {
        std::cerr << "Failed to subscribe to topic: " << error.message() << std::endl;
        return 1;
    }
    
    std::cout << "Subscribed to sensors/temperature" << std::endl;
    std::cout << "Waiting for sensor data..." << std::endl;
    
    // Keep running.
    while (true) {
        using namespace std::chrono_literals;
        std::this_thread::sleep_for(1s);
    }
    
    return 0;
}
2. Crea e impacchetta il componente

Alcune lingue richiedono la creazione o la creazione di pacchetti prima della distribuzione.

Python

Python non richiede la compilazione. Il componente può utilizzare direttamente il file.py.

Java

Per creare un JAR eseguibile con tutte le dipendenze raggruppate:

  1. Crea un pom.xml file nella directory del tuo progetto:

    <?xml version="1.0" encoding="UTF-8"?>
<project xmlns="http://maven.apache.org/POM/4.0.0"
         xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
         xsi:schemaLocation="http://maven.apache.org/POM/4.0.0 http://maven.apache.org/xsd/maven-4.0.0.xsd">
    <modelVersion>4.0.0</modelVersion>

    <!-- Basic project information: organization, component name, and version -->
    <groupId>com.example</groupId>
    <artifactId>temperature-processor</artifactId>
    <version>1.0.0</version>

    <properties>
        <!-- Java 11 LTS (Long Term Support) is recommended for Greengrass v2 components -->
        <maven.compiler.source>11</maven.compiler.source>
        <maven.compiler.target>11</maven.compiler.target>
    </properties>

    <dependencies>
        <!-- AWS IoT Device SDK for Java - provides IPC client for Greengrass v2 local communication -->
        <dependency>
            <groupId>software.amazon.awssdk.iotdevicesdk</groupId>
            <artifactId>aws-iot-device-sdk</artifactId>
            <version>1.25.1</version>
        </dependency>
    </dependencies>

    <build>
        <plugins>
            <!-- Maven Shade Plugin - creates a standalone JAR with all dependencies included for Greengrass deployment -->
            <plugin>
                <groupId>org.apache.maven.plugins</groupId>
                <artifactId>maven-shade-plugin</artifactId>
                <version>3.2.4</version>
                <executions>
                    <execution>
                        <phase>package</phase>
                        <goals>
                            <goal>shade</goal>
                        </goals>
                        <configuration>
                            <transformers>
                                <!-- Set the main class for the executable JAR -->
                                <transformer implementation="org.apache.maven.plugins.shade.resource.ManifestResourceTransformer">
                                    <mainClass>TemperatureProcessor</mainClass>
                                </transformer>
                            </transformers>
                            <filters>
                                <!-- Exclude signature files to avoid security exceptions -->
                                <filter>
                                    <artifact>*:*</artifact>
                                    <excludes>
                                        <exclude>META-INF/*.SF</exclude>
                                        <exclude>META-INF/*.DSA</exclude>
                                        <exclude>META-INF/*.RSA</exclude>
                                    </excludes>
                                </filter>
                            </filters>
                        </configuration>
                    </execution>
                </executions>
            </plugin>
        </plugins>
    </build>
</project>

  2. Costruisci il JAR:

    mvn clean package

    Questo crea target/temperature-processor-1.0.0.jar con tutte le dipendenze incluse.

  3. Carica il JAR nel tuo bucket S3 per la distribuzione.

JavaScript

Per impacchettare il componente Node.js con tutte le dipendenze:

  1. Crea un package.json file:

    {
  "name": "temperature-processor",
  "version": "1.0.0",
  "description": "Temperature processor component for Greengrass v2",
  "main": "TemperatureProcessor.js",
  "dependencies": {
    "aws-iot-device-sdk-v2": "^1.21.0"
  },
  "engines": {
    "node": ">=14.0.0"
  }
}

  2. Installa le dipendenze sulla tua macchina di sviluppo:

    npm install

    Questo crea una node_modules cartella contenente la AWS SDK per dispositivi AWS IoT v2.

  3. Package per l'implementazione:

    zip -r TemperatureProcessor.zip TemperatureProcessor.js node_modules/ package.json

  4. Carica il file zip nel tuo bucket S3 per la distribuzione.

Nota

Sul dispositivo Greengrass deve essere installato il runtime Node.js (versione 14 o successiva). Non è necessario eseguirlo npm install sul dispositivo principale Greengrass poiché l'elemento del componente include tutte le dipendenze nella cartella in bundle. node_modules

C

Prerequisiti:

Per creare l'SDK e il componente, sono necessarie le seguenti dipendenze di compilazione:

  • GCC o Clang

  • CMake (almeno la versione 3.22)

  • Make or Ninja

Installa le dipendenze di compilazione:

Su Ubuntu/Debian:

sudo apt install build-essential cmake

Su Amazon Linux:

sudo yum install gcc cmake make

Crea un CMake file Lists.txt per il tuo componente:

cmake_minimum_required(VERSION 3.10)
project(TemperatureProcessor C)

set(CMAKE_C_STANDARD 11)

# Add AWS Greengrass Component SDK
add_subdirectory(aws-greengrass-component-sdk)

# Build your component executable
add_executable(temperature_processor temperature_processor.c)
target_link_libraries(temperature_processor gg-sdk)

Procedura di creazione:

# Clone the AWS Greengrass Component SDK into your project
git clone https://github.com/aws-greengrass/aws-greengrass-component-sdk.git

# Build your component
cmake -B build -D CMAKE_BUILD_TYPE=MinSizeRel
make -C build -j$(nproc)

# The binary 'temperature_processor' is in ./build/
# Upload this binary to S3 for deployment
C++

Prerequisiti:

Per creare l'SDK e il componente, avrai bisogno delle seguenti dipendenze di compilazione:

  • GCC o Clang con supporto C++20

  • CMake (almeno la versione 3.22)

  • Make or Ninja

Installa le dipendenze di compilazione:

Su Ubuntu/Debian:

sudo apt install build-essential cmake

Su Amazon Linux:

sudo yum install gcc-c++ cmake make

Crea un CMake file Lists.txt per il tuo componente:

cmake_minimum_required(VERSION 3.10)
project(TemperatureProcessor CXX)

set(CMAKE_CXX_STANDARD 20)

# Add SDK as subdirectory
add_subdirectory(aws-greengrass-component-sdk)

# Add C++ SDK subdirectory
add_subdirectory(aws-greengrass-component-sdk/cpp)

add_executable(temperature_processor temperature_processor.cpp)
target_link_libraries(temperature_processor gg-sdk++)

Procedura di creazione:

# Clone the AWS Greengrass Component SDK into your project
git clone https://github.com/aws-greengrass/aws-greengrass-component-sdk.git

# Build your component
cmake -B build -D CMAKE_BUILD_TYPE=MinSizeRel
make -C build -j$(nproc)

# The binary 'temperature_processor' will be in ./build/
# Upload this binary to S3 for deployment
3. Ricetta del componente

Aggiorna l'array «resources» con gli argomenti effettivi utilizzati dal componente.

Python
{
  "RecipeFormatVersion": "2020-01-25",
  "ComponentName": "com.example.TemperatureProcessor",
  "ComponentVersion": "1.0.0",
  "ComponentType": "aws.greengrass.generic",
  "ComponentDescription": "Receives sensor data and forwards alerts to AlertHandler",
  "ComponentPublisher": "[Your Company]",
  "ComponentConfiguration": {
    "DefaultConfiguration": {
      "accessControl": {
        "aws.greengrass.ipc.pubsub": {
          "com.example.TemperatureProcessor:pubsub:1": {
            "policyDescription": "Allows access to subscribe to sensor topics",
            "operations": [
              "aws.greengrass#SubscribeToTopic"
            ],
            "resources": [
              "sensors/temperature"
            ]
          },
          "com.example.TemperatureProcessor:pubsub:2": {
            "policyDescription": "Allows access to publish to alert topics",
            "operations": [
              "aws.greengrass#PublishToTopic"
            ],
            "resources": [
              "component/alerts"
            ]
          }
        }
      }
    }
  },
  "Manifests": [
    {
      "Platform": {
        "os": "linux",
        "runtime": "*"
      },
      "Lifecycle": {
        "run": "python3 -u {artifacts:path}/temperature_processor.py"
      },
      "Artifacts": [
        {
          "Uri": "s3://YOUR-BUCKET/artifacts/com.example.TemperatureProcessor/1.0.0/temperature_processor.py"
        }
      ]
    }
  ]
}
Java
{
  "RecipeFormatVersion": "2020-01-25",
  "ComponentName": "com.example.TemperatureProcessor",
  "ComponentVersion": "1.0.0",
  "ComponentType": "aws.greengrass.generic",
  "ComponentDescription": "Receives sensor data and forwards alerts to AlertHandler",
  "ComponentPublisher": "[Your Company]",
  "ComponentConfiguration": {
    "DefaultConfiguration": {
      "accessControl": {
        "aws.greengrass.ipc.pubsub": {
          "com.example.TemperatureProcessor:pubsub:1": {
            "policyDescription": "Allows access to subscribe to sensor topics",
            "operations": [
              "aws.greengrass#SubscribeToTopic"
            ],
            "resources": [
              "sensors/temperature"
            ]
          },
          "com.example.TemperatureProcessor:pubsub:2": {
            "policyDescription": "Allows access to publish to alert topics",
            "operations": [
              "aws.greengrass#PublishToTopic"
            ],
            "resources": [
              "component/alerts"
            ]
          }
        }
      }
    }
  },
  "Manifests": [
    {
      "Platform": {
        "os": "linux",
        "runtime": "*"
      },
      "Lifecycle": {
        "run": "java -jar {artifacts:path}/TemperatureProcessor.jar"
      },
      "Artifacts": [
        {
          "Uri": "s3://YOUR-BUCKET/artifacts/com.example.TemperatureProcessor/1.0.0/TemperatureProcessor.jar"
        }
      ]
    }
  ]
}
JavaScript
{
  "RecipeFormatVersion": "2020-01-25",
  "ComponentName": "com.example.TemperatureProcessor",
  "ComponentVersion": "1.0.0",
  "ComponentType": "aws.greengrass.generic",
  "ComponentDescription": "Receives sensor data and forwards alerts to AlertHandler",
  "ComponentPublisher": "[Your Company]",
  "ComponentConfiguration": {
    "DefaultConfiguration": {
      "accessControl": {
        "aws.greengrass.ipc.pubsub": {
          "com.example.TemperatureProcessor:pubsub:1": {
            "policyDescription": "Allows access to subscribe to sensor topics",
            "operations": [
              "aws.greengrass#SubscribeToTopic"
            ],
            "resources": [
              "sensors/temperature"
            ]
          },
          "com.example.TemperatureProcessor:pubsub:2": {
            "policyDescription": "Allows access to publish to alert topics",
            "operations": [
              "aws.greengrass#PublishToTopic"
            ],
            "resources": [
              "component/alerts"
            ]
          }
        }
      }
    }
  },
  "Manifests": [
    {
      "Platform": {
        "os": "linux",
        "runtime": "*"
      },
      "Lifecycle": {
        "run": "cd {artifacts:decompressedPath}/TemperatureProcessor && node TemperatureProcessor.js"
      },
      "Artifacts": [
        {
          "Uri": "s3://YOUR-BUCKET/artifacts/com.example.TemperatureProcessor/1.0.0/TemperatureProcessor.zip",
          "Unarchive": "ZIP"
        }
      ]
    }
  ]
}
C/C++
{
  "RecipeFormatVersion": "2020-01-25",
  "ComponentName": "com.example.TemperatureProcessor",
  "ComponentVersion": "1.0.0",
  "ComponentType": "aws.greengrass.generic",
  "ComponentDescription": "Receives sensor data and forwards alerts to AlertHandler",
  "ComponentPublisher": "[Your Company]",
  "ComponentConfiguration": {
    "DefaultConfiguration": {
      "accessControl": {
        "aws.greengrass.ipc.pubsub": {
          "com.example.TemperatureProcessor:pubsub:1": {
            "policyDescription": "Allows access to subscribe to sensor topics",
            "operations": [
              "aws.greengrass#SubscribeToTopic"
            ],
            "resources": [
              "sensors/temperature"
            ]
          },
          "com.example.TemperatureProcessor:pubsub:2": {
            "policyDescription": "Allows access to publish to alert topics",
            "operations": [
              "aws.greengrass#PublishToTopic"
            ],
            "resources": [
              "component/alerts"
            ]
          }
        }
      }
    }
  },
  "Manifests": [
    {
      "Platform": {
        "os": "linux",
        "runtime": "*"
      },
      "Lifecycle": {
        "run": "{artifacts:path}/temperature_processor"
      },
      "Artifacts": [
        {
          "Uri": "s3://YOUR-BUCKET/artifacts/com.example.TemperatureProcessor/1.0.0/temperature_processor"
        }
      ]
    }
  ]
}

Scenario 2: Comunicazione nel cloud

Questo scenario dimostra la conversione di una funzione Lambda V1 che comunica AWS IoT Core con in un componente generico V2.

Architettura dell'applicazione

Questo esempio utilizza un'architettura connessa al cloud:

  • AWS IoT Core invia comandi al dispositivo

  • Controller Lambda riceve i comandi e li elabora

  • Il controller Lambda invia i dati di telemetria a AWS IoT Core

Questo esempio si concentra sul controller Lambda, che dimostra sia la ricezione di messaggi da che la pubblicazione di messaggi. AWS IoT Core

Abbonamenti di gruppo V1

In AWS IoT Greengrass V1, i seguenti abbonamenti di gruppo abilitano la comunicazione tra la funzione Lambda e: AWS IoT Core

Abbonamento 1: IoT Cloud → Lambda

  • Fonte: IoT Cloud

  • Obiettivo: Lambda () DeviceController

  • Argomento: commands/device1

Abbonamento 2: Lambda → IoT Cloud

  • Fonte: Lambda () DeviceController

  • Obiettivo: IoT Cloud

  • Argomento: telemetria/dispositivo1

Funzione Lambda del controller (V1)

Python
import greengrasssdk
import json
import time

iot_client = greengrasssdk.client('iot-data')

def lambda_handler(event, context):
    """
    Receives commands from IoT Core,
    processes them, and sends telemetry back to cloud
    """
    # Receive command from IoT Core.
    command = event.get('command')
    device_id = event.get('device_id', 'device1')

    print(f"Received command from cloud: {command}")

    # Process command.
    if command == 'get_status':
        status = get_device_status()

        # Send telemetry back to IoT Core.
        telemetry_data = {
            'device_id': device_id,
            'status': status,
            'timestamp': time.time()
        }

        iot_client.publish(
            topic=f'telemetry/{device_id}',
            payload=json.dumps(telemetry_data)
        )

        print(f"Telemetry sent to cloud: {telemetry_data}")

    return {'statusCode': 200}

def get_device_status():
    """Get current device status"""
    # Simulate getting device status.
    return 'online'
Java
import com.amazonaws.services.lambda.runtime.Context;
import com.amazonaws.greengrass.javasdk.IotDataClient;
import com.amazonaws.greengrass.javasdk.model.PublishRequest;
import com.google.gson.Gson;
import java.nio.ByteBuffer;
import java.nio.charset.StandardCharsets;
import java.util.HashMap;
import java.util.Map;

public class DeviceControllerLambda {
    private static final Gson gson = new Gson();
    private final IotDataClient iotDataClient;

    public DeviceControllerLambda() {
        this.iotDataClient = new IotDataClient();
    }

    public String handleRequest(Map<String, Object> event, Context context) {
        /*
         * Receives commands from IoT Core,
         * processes them, and sends telemetry back to cloud
         */

        // Receive command from IoT Core.
        String command = (String) event.get("command");
        String deviceId = event.containsKey("device_id") ? 
            (String) event.get("device_id") : "device1";

        System.out.println("Received command from cloud: " + command);

        // Process command.
        if ("get_status".equals(command)) {
            String status = getDeviceStatus();

            // Send telemetry back to IoT Core.
            Map<String, Object> telemetryData = new HashMap<>();
            telemetryData.put("device_id", deviceId);
            telemetryData.put("status", status);
            telemetryData.put("timestamp", System.currentTimeMillis() / 1000.0);

            String payload = gson.toJson(telemetryData);
            PublishRequest publishRequest = new PublishRequest()
                .withTopic("telemetry/" + deviceId)
                .withPayload(ByteBuffer.wrap(payload.getBytes(StandardCharsets.UTF_8)));

            iotDataClient.publish(publishRequest);

            System.out.println("Telemetry sent to cloud: " + telemetryData);
        }

        return "Success";
    }

    private String getDeviceStatus() {
        // Simulate getting device status.
        return "online";
    }
}
JavaScript
const greengrasssdk = require('aws-greengrass-core-sdk');

const iotClient = new greengrasssdk.IotData();

/**
 * Receives commands from IoT Core and sends telemetry back.
 */
exports.handler = function(event, context) {
    console.log('Received command from IoT Core:', JSON.stringify(event));
    
    const command = event.command;
    const deviceId = event.device_id || 'device1';
    
    console.log(`Processing command: ${command}`);
    
    if (command === 'get_status') {
        const status = 'online';
        
        const telemetryData = {
            device_id: deviceId,
            status: status,
            timestamp: Date.now() / 1000
        };
        
        // Publish telemetry to IoT Core using greengrasssdk.
        const params = {
            topic: `telemetry/${deviceId}`,
            payload: JSON.stringify(telemetryData)
        };
        
        iotClient.publish(params, (err) => {
            if (err) {
                console.error('Error publishing telemetry:', err);
                context.fail(err);
            } else {
                console.log('Telemetry sent to IoT Core:', JSON.stringify(telemetryData));
                context.succeed('Success');
            }
        });
    } else {
        context.succeed('Success');
    }
};
C
#include <aws/greengrass/greengrasssdk.h>
#include <stdio.h>
#include <string.h>
#include <jansson.h>
#include <time.h>

static aws_greengrass_iot_data_client *iot_client = NULL;

const char* get_device_status(void) {
    // Simulate getting device status.
    return "online";
}

void on_cloud_command(const char *topic, const uint8_t *payload, size_t payload_len, void *user_data) {
    // Parse incoming command from IoT Core.
    char *payload_str = strndup((char *)payload, payload_len);
    json_error_t error;
    json_t *event = json_loads(payload_str, 0, &error);
    free(payload_str);
    
    if (!event) {
        fprintf(stderr, "Error parsing JSON: %s\n", error.text);
        return;
    }
    
    // Extract command and device_id.
    json_t *command_obj = json_object_get(event, "command");
    json_t *device_id_obj = json_object_get(event, "device_id");
    
    const char *command = json_string_value(command_obj);
    const char *device_id = device_id_obj ? json_string_value(device_id_obj) : "device1";
    
    printf("Received command from cloud: %s\n", command);
    
    // Process command.
    if (command && strcmp(command, "get_status") == 0) {
        const char *status = get_device_status();
        
        // Send telemetry back to IoT Core.
        json_t *telemetry_data = json_object();
        json_object_set_new(telemetry_data, "device_id", json_string(device_id));
        json_object_set_new(telemetry_data, "status", json_string(status));
        json_object_set_new(telemetry_data, "timestamp", json_real(time(NULL)));
        
        char *telemetry_payload = json_dumps(telemetry_data, JSON_COMPACT);
        
        // Publish telemetry to IoT Core.
        char telemetry_topic[256];
        snprintf(telemetry_topic, sizeof(telemetry_topic), "telemetry/%s", device_id);
        
        aws_greengrass_publish_params params = {
            .topic = telemetry_topic,
            .payload = (uint8_t *)telemetry_payload,
            .payload_len = strlen(telemetry_payload)
        };
        
        aws_greengrass_iot_data_publish(iot_client, &params);
        
        printf("Telemetry sent to cloud: %s\n", telemetry_payload);
    
        free(telemetry_payload);
        json_decref(telemetry_data);
    }
    
    json_decref(event);
}

int main(int argc, char *argv[]) {
    // Initialize Greengrass SDK.
    iot_client = aws_greengrass_iot_data_client_new();
    
    // Subscribe to commands from IoT Core.
    aws_greengrass_subscribe_params subscribe_params = {
        .topic = "commands/device1",
        .callback = on_cloud_command,
        .user_data = NULL
    };
    
    aws_greengrass_iot_data_subscribe(iot_client, &subscribe_params);
    
    printf("Device Controller Lambda started\n");
    printf("Subscribed to commands/device1\n");
    printf("Waiting for commands from IoT Core...\n");
    
    // Keep the Lambda running.
    while (1) {
        sleep(1);
    }
    
    return 0;
}
C++
#include <aws/greengrass/greengrasssdk.h>
#include <iostream>
#include <string>
#include <memory>
#include <jansson.h>
#include <ctime>
#include <unistd.h>

class DeviceController {
private:
    std::unique_ptr<aws_greengrass_iot_data_client, decltype(&aws_greengrass_iot_data_client_destroy)> iot_client;
    
    static void message_callback_wrapper(const char *topic, const uint8_t *payload, 
                                        size_t payload_len, void *user_data) {
        auto* controller = static_cast<DeviceController*>(user_data);
        controller->on_cloud_command(topic, payload, payload_len);
    }
    
    std::string get_device_status() {
        // Simulate getting device status.
        return "online";
    }

public:
    DeviceController() 
        : iot_client(aws_greengrass_iot_data_client_new(), 
                     aws_greengrass_iot_data_client_destroy) {
        if (!iot_client) {
            throw std::runtime_error("Failed to create Greengrass IoT client");
        }
    }
    
    void on_cloud_command(const char *topic, const uint8_t *payload, size_t payload_len) {
        // Parse incoming command from IoT Core.
        std::string payload_str(reinterpret_cast<const char*>(payload), payload_len);
        
        json_error_t error;
        json_t *event = json_loads(payload_str.c_str(), 0, &error);
        
        if (!event) {
            std::cerr << "Error parsing JSON: " << error.text << std::endl;
            return;
        }
        
        // Extract command and device_id.
        json_t *command_obj = json_object_get(event, "command");
        json_t *device_id_obj = json_object_get(event, "device_id");
        
        const char *command = json_string_value(command_obj);
        const char *device_id = device_id_obj ? json_string_value(device_id_obj) : "device1";
        
        std::cout << "Received command from cloud: " << command << std::endl;
        
        // Process command.
        if (command && std::string(command) == "get_status") {
            std::string status = get_device_status();
            
            // Send telemetry back to IoT Core.
            json_t *telemetry_data = json_object();
            json_object_set_new(telemetry_data, "device_id", json_string(device_id));
            json_object_set_new(telemetry_data, "status", json_string(status.c_str()));
            json_object_set_new(telemetry_data, "timestamp", json_real(std::time(nullptr)));
            
            char *telemetry_payload = json_dumps(telemetry_data, JSON_COMPACT);
            
            // Publish telemetry to IoT Core.
            std::string telemetry_topic = "telemetry/" + std::string(device_id);
            
            aws_greengrass_publish_params params = {
                .topic = telemetry_topic.c_str(),
                .payload = reinterpret_cast<uint8_t*>(telemetry_payload),
                .payload_len = strlen(telemetry_payload)
            };
            
            aws_greengrass_iot_data_publish(iot_client.get(), &params);
            
            std::cout << "Telemetry sent to cloud: " << telemetry_payload << std::endl;
            
            free(telemetry_payload);
            json_decref(telemetry_data);
        }
        
        json_decref(event);
    }
    
    void subscribe_to_topic(const std::string& topic) {
        aws_greengrass_subscribe_params subscribe_params = {
            .topic = topic.c_str(),
            .callback = message_callback_wrapper,
            .user_data = this
        };
        
        aws_greengrass_iot_data_subscribe(iot_client.get(), &subscribe_params);
        
        std::cout << "Device Controller Lambda started" << std::endl;
        std::cout << "Subscribed to " << topic << std::endl;
        std::cout << "Waiting for commands from IoT Core..." << std::endl;
    }
    
    void run() {
        // Keep the Lambda running.
        while (true) {
            sleep(1);
        }
    }
};

int main(int argc, char *argv[]) {
    try {
        DeviceController controller;
        controller.subscribe_to_topic("commands/device1");
        controller.run();
    } catch (const std::exception& e) {
        std::cerr << "Error: " << e.what() << std::endl;
        return 1;
    }
    
    return 0;
}

Componente generico (V2)

Per ottenere la stessa funzionalità in AWS IoT Greengrass V2, crea un componente generico con quanto segue:

1. Codice del componente
Python

Prerequisiti: prima di utilizzare questo codice componente, installa e verifica il SDK per dispositivi AWS IoT for Python sul tuo dispositivo Greengrass:

# Install the SDK
pip3 install awsiotsdk

# Verify installation
python3 -c "import awsiot.greengrasscoreipc.clientv2; print('SDK installed successfully')"

Se riscontrate conflitti di dipendenza durante l'installazione, provate a installare una versione specifica di. SDK per dispositivi AWS IoT

Se il comando di verifica stampa «SDK installato correttamente», sei pronto per utilizzare il codice del componente:

from awsiot.greengrasscoreipc.clientv2 import GreengrassCoreIPCClientV2
from awsiot.greengrasscoreipc.model import QOS
import json
import time

ipc_client = GreengrassCoreIPCClientV2()

def on_command(event):
    """
    Receives commands from IoT Core,
    processes them, and sends telemetry back to cloud
    """
    try:
        # Receive command from IoT Core.
        data = json.loads(event.message.payload.decode('utf-8'))
        command = data.get('command')
        device_id = data.get('device_id', 'device1')

        print(f"Received command from cloud: {command}")

        # Process command.
        if command == 'get_status':
            status = get_device_status()

            # Send telemetry back to IoT Core.
            telemetry_data = {
                'device_id': device_id,
                'status': status,
                'timestamp': time.time()
            }

            ipc_client.publish_to_iot_core(
                topic_name=f'telemetry/{device_id}',
                qos=QOS.AT_LEAST_ONCE,
                payload=json.dumps(telemetry_data).encode('utf-8')
            )

            print(f"Telemetry sent to cloud: {telemetry_data}")

    except Exception as e:
        print(f"Error processing command: {e}")

def get_device_status():
    """Get current device status"""
    # Simulate getting device status.
    return 'online'

def main():
    print("Device Controller component starting...")

    # Subscribe to commands from IoT Core.
    ipc_client.subscribe_to_iot_core(
        topic_name='commands/device1',
        qos=QOS.AT_LEAST_ONCE,
        on_stream_event=on_command
    )

    print("Subscribed to commands/device1 from IoT Core")
    print("Waiting for commands from cloud...")

    # Keep running.
    while True:
        time.sleep(1)

if __name__ == '__main__':
    main()
Java
import software.amazon.awssdk.aws.greengrass.GreengrassCoreIPCClientV2;
import software.amazon.awssdk.aws.greengrass.model.QOS;
import software.amazon.awssdk.aws.greengrass.model.SubscribeToIoTCoreRequest;
import software.amazon.awssdk.aws.greengrass.model.IoTCoreMessage;
import software.amazon.awssdk.aws.greengrass.model.PublishToIoTCoreRequest;
import java.nio.charset.StandardCharsets;
import java.util.Optional;
import java.util.regex.Pattern;
import java.util.regex.Matcher;

public class DeviceController {
    private static GreengrassCoreIPCClientV2 ipcClient;

    public static void main(String[] args) {
        System.out.println("Device Controller component starting...");
        
        try (GreengrassCoreIPCClientV2 client = GreengrassCoreIPCClientV2.builder().build()) {
            ipcClient = client;

            SubscribeToIoTCoreRequest subscribeRequest = new SubscribeToIoTCoreRequest()
                .withTopicName("commands/device1")
                .withQos(QOS.AT_LEAST_ONCE);

            ipcClient.subscribeToIoTCore(
                subscribeRequest,
                DeviceController::onCommand,
                Optional.empty(),
                Optional.empty()
            );

            System.out.println("Subscribed to commands/device1 from IoT Core");
            System.out.println("Waiting for commands from cloud...");

            while (true) {
                Thread.sleep(1000);
            }
        } catch (Exception e) {
            System.err.println("Error: " + e.getMessage());
            e.printStackTrace();
        }
    }

    public static void onCommand(IoTCoreMessage message) {
        try {
            String payload = new String(message.getMessage().getPayload(), StandardCharsets.UTF_8);
            
            // Simple JSON parsing.
            String command = extractJsonValue(payload, "command");
            String deviceId = extractJsonValue(payload, "device_id");
            if (deviceId == null || deviceId.isEmpty()) {
                deviceId = "device1";
            }

            System.out.println("Received command from cloud: " + command);

            if ("get_status".equals(command)) {
                String status = getDeviceStatus();

                // Build JSON manually.
                String telemetryJson = String.format(
                    "{\"device_id\":\"%s\",\"status\":\"%s\",\"timestamp\":%.3f}",
                    deviceId, status, System.currentTimeMillis() / 1000.0
                );
                byte[] telemetryBytes = telemetryJson.getBytes(StandardCharsets.UTF_8);

                PublishToIoTCoreRequest publishRequest = new PublishToIoTCoreRequest()
                    .withTopicName("telemetry/" + deviceId)
                    .withQos(QOS.AT_LEAST_ONCE)
                    .withPayload(telemetryBytes);

                ipcClient.publishToIoTCore(publishRequest);

                System.out.println("Telemetry sent to cloud: " + telemetryJson);
            }
        } catch (Exception e) {
            System.err.println("Error processing command: " + e.getMessage());
        }
    }

    private static String extractJsonValue(String json, String key) {
        Pattern pattern = Pattern.compile("\"" + Pattern.quote(key) + "\"\\s*:\\s*\"([^\"]+)\"");
        Matcher matcher = pattern.matcher(json);
        return matcher.find() ? matcher.group(1) : null;
    }

    private static String getDeviceStatus() {
        return "online";
    }
}
JavaScript
const greengrasscoreipc = require('aws-iot-device-sdk-v2').greengrasscoreipc;

class DeviceController {
    constructor() {
        this.ipcClient = null;
    }

    async start() {
        console.log('Device Controller component starting...');
        
        try {
            this.ipcClient = greengrasscoreipc.createClient();
            await this.ipcClient.connect();
            
            const subscribeRequest = {
                topicName: 'commands/device1',
                qos: 1
            };

            const streamingOperation = this.ipcClient.subscribeToIoTCore(subscribeRequest);
            
            streamingOperation.on('message', (message) => {
                this.onCommand(message);
            });
            
            streamingOperation.on('streamError', (error) => {
                console.error('Stream error:', error);
            });
            
            streamingOperation.on('ended', () => {
                console.log('Subscription stream ended');
            });
            
            await streamingOperation.activate();
            
            console.log('Subscribed to commands/device1 from IoT Core');
            console.log('Waiting for commands from cloud...');
            
        } catch (error) {
            console.error('Error starting component:', error);
            process.exit(1);
        }
    }

    async onCommand(message) {
        try {
            const payload = message.message.payload.toString('utf-8');
            const data = JSON.parse(payload);
            
            const command = data.command;
            const deviceId = data.device_id || 'device1';
            
            console.log(`Received command from cloud: ${command}`);
            
            if (command === 'get_status') {
                const status = this.getDeviceStatus();
                
                const telemetryData = {
                    device_id: deviceId,
                    status: status,
                    timestamp: Date.now() / 1000
                };
                
                const telemetryJson = JSON.stringify(telemetryData);
                
                const publishRequest = {
                    topicName: `telemetry/${deviceId}`,
                    qos: 1,
                    payload: Buffer.from(telemetryJson, 'utf-8')
                };
                
                await this.ipcClient.publishToIoTCore(publishRequest);
                console.log(`Telemetry sent to cloud: ${telemetryJson}`);
            }
            
        } catch (error) {
            console.error('Error processing command:', error);
        }
    }

    getDeviceStatus() {
        return 'online';
    }
}

// Start the component.
const controller = new DeviceController();
controller.start();
C
#include <gg/buffer.h>
#include <gg/error.h>
#include <gg/ipc/client.h>
#include <gg/map.h>
#include <gg/object.h>
#include <gg/sdk.h>
#include <unistd.h>
#include <stdbool.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <time.h>
#include <pthread.h>

#define COMMAND_TOPIC "commands/device1"
#define TELEMETRY_TOPIC "telemetry/device1"

typedef struct {
    char device_id[64];
    char command[64];
} CommandData;

static pthread_mutex_t command_mutex = PTHREAD_MUTEX_INITIALIZER;
static pthread_cond_t command_cond = PTHREAD_COND_INITIALIZER;
static CommandData pending_command;
static bool has_pending_command = false;

const char* get_device_status(void) {
    // Simulate getting device status.
    return "online";
}

static void *telemetry_publisher_thread(void *arg) {
    (void) arg;
    
    while (true) {
        pthread_mutex_lock(&command_mutex);
        while (!has_pending_command) {
            pthread_cond_wait(&command_cond, &command_mutex);
        }
        
        CommandData cmd = pending_command;
        has_pending_command = false;
        pthread_mutex_unlock(&command_mutex);
        
        // Process command.
        if (strcmp(cmd.command, "get_status") == 0) {
            const char *status = get_device_status();
            
            // Create telemetry JSON string.
            char telemetry_json[512];
            snprintf(telemetry_json, sizeof(telemetry_json),
                     "{\"device_id\":\"%s\",\"status\":\"%s\",\"timestamp\":%ld}",
                     cmd.device_id, status, time(NULL));
            
            GgBuffer telemetry_buf = {
                .data = (uint8_t *)telemetry_json,
                .len = strlen(telemetry_json)
            };
            
            // Publish telemetry to IoT Core.
            GgError ret = ggipc_publish_to_iot_core(GG_STR(TELEMETRY_TOPIC), telemetry_buf, 0);
            
            if (ret != GG_ERR_OK) {
                fprintf(stderr, "Failed to publish telemetry to IoT Core\n");
            } else {
                printf("Telemetry sent to cloud: device_id=%s, status=%s\n", cmd.device_id, status);
            }
        }
    }
    
    return NULL;
}

static void on_cloud_command(
    void *ctx, GgBuffer topic, GgBuffer payload, GgIpcSubscriptionHandle handle
) {
    (void) ctx;
    (void) topic;
    (void) handle;
    
    printf("Received command from IoT Core: %.*s\n", (int)payload.len, payload.data);
    
    // Parse JSON payload (comes as raw buffer from IoT Core).
    // For simplicity, we'll do basic string parsing.
    
    // Extract command and device_id from JSON string.
    char payload_str[512];
    snprintf(payload_str, sizeof(payload_str), "%.*s", (int)payload.len, payload.data);
    
    // Simple JSON parsing (looking for "command":"get_status").
    char *command_start = strstr(payload_str, "\"command\"");
    char *device_id_start = strstr(payload_str, "\"device_id\"");
    
    if (command_start) {
        pthread_mutex_lock(&command_mutex);
        
        char *cmd_value = strstr(command_start, ":");
        if (cmd_value) {
            cmd_value = strchr(cmd_value, '"');
            if (cmd_value) {
                cmd_value++;
                char *cmd_end = strchr(cmd_value, '"');
                if (cmd_end) {
                    size_t cmd_len = cmd_end - cmd_value;
                    if (cmd_len < sizeof(pending_command.command)) {
                        strncpy(pending_command.command, cmd_value, cmd_len);
                        pending_command.command[cmd_len] = '\0';
                    }
                }
            }
        }
        
        // Extract device_id or use default.
        if (device_id_start) {
            char *dev_value = strstr(device_id_start, ":");
            if (dev_value) {
                dev_value = strchr(dev_value, '"');
                if (dev_value) {
                    dev_value++;
                    char *dev_end = strchr(dev_value, '"');
                    if (dev_end) {
                        size_t dev_len = dev_end - dev_value;
                        if (dev_len < sizeof(pending_command.device_id)) {
                            strncpy(pending_command.device_id, dev_value, dev_len);
                            pending_command.device_id[dev_len] = '\0';
                        }
                    }
                }
            }
        } else {
            strcpy(pending_command.device_id, "device1");
        }
        
        printf("Received command from cloud: %s\n", pending_command.command);
        
        has_pending_command = true;
        pthread_cond_signal(&command_cond);
        pthread_mutex_unlock(&command_mutex);
    }
}

int main(void) {
    setvbuf(stdout, NULL, _IONBF, 0);
    printf("Device Controller component starting...\n");
    
    gg_sdk_init();
    
    GgError ret = ggipc_connect();
    if (ret != GG_ERR_OK) {
        fprintf(stderr, "Failed to connect to Greengrass nucleus\n");
        exit(1);
    }
    printf("Connected to Greengrass IPC\n");
    
    // Start telemetry publisher thread.
    pthread_t telemetry_thread;
    if (pthread_create(&telemetry_thread, NULL, telemetry_publisher_thread, NULL) != 0) {
        fprintf(stderr, "Failed to create telemetry publisher thread\n");
        exit(1);
    }
    
    // Subscribe to commands from IoT Core.
    GgIpcSubscriptionHandle handle;
    ret = ggipc_subscribe_to_iot_core(
        GG_STR(COMMAND_TOPIC),
        0,
        &on_cloud_command,
        NULL,
        &handle
    );
    
    if (ret != GG_ERR_OK) {
        fprintf(stderr, "Failed to subscribe to IoT Core topic\n");
        exit(1);
    }
    
    printf("Subscribed to %s\n", COMMAND_TOPIC);
    printf("Waiting for commands from IoT Core...\n");
    
    while (true) {
        sleep(1);
    }
    
    return 0;
}
C++
#include <gg/ipc/client.hpp>
#include <gg/buffer.hpp>
#include <gg/object.hpp>
#include <gg/types.hpp>

#include <chrono>
#include <condition_variable>
#include <ctime>
#include <iostream>
#include <mutex>
#include <string>
#include <string_view>
#include <thread>

constexpr std::string_view COMMAND_TOPIC = "commands/device1";
constexpr std::string_view TELEMETRY_TOPIC = "telemetry/device1";

struct CommandData {
    std::string device_id;
    std::string command;
};

static std::mutex command_mutex;
static std::condition_variable command_cv;
static CommandData pending_command;
static bool has_pending_command = false;

std::string get_device_status() {
    // Simulate getting device status.
    return "online";
}

void telemetry_publisher_thread() {
    auto& client = gg::ipc::Client::get();
    
    while (true) {
        std::unique_lock<std::mutex> lock(command_mutex);
        command_cv.wait(lock, [] { return has_pending_command; });
        
        CommandData cmd = pending_command;
        has_pending_command = false;
        lock.unlock();
        
        // Process command.
        if (cmd.command == "get_status") {
            std::string status = get_device_status();
            
            // Get current timestamp.
            auto now = std::time(nullptr);
            
            // Create telemetry JSON payload.
            std::string telemetry_payload = "{\"device_id\":\"" + cmd.device_id + 
                                          "\",\"status\":\"" + status + 
                                          "\",\"timestamp\":" + std::to_string(now) + "}";
            
            // Publish telemetry to IoT Core.
            gg::Buffer telemetry_buffer(telemetry_payload);
            auto error = client.publish_to_iot_core(TELEMETRY_TOPIC, telemetry_buffer);
            
            if (error) {
                std::cerr << "Failed to publish telemetry to IoT Core: " 
                         << error.message() << std::endl;
            } else {
                std::cout << "Telemetry sent to cloud: device_id=" << cmd.device_id 
                         << ", status=" << status << std::endl;
            }
        }
    }
}

class CloudCommandCallback : public gg::ipc::IoTCoreTopicCallback {
    void operator()(
        std::string_view topic,
        gg::Object payload,
        gg::ipc::Subscription& handle
    ) override {
        (void) topic;
        (void) handle;
        
        // Payload is a Buffer containing JSON string from IoT Core.
        if (payload.index() != GG_TYPE_BUF) {
            std::cerr << "Expected Buffer message\n";
            return;
        }
        
        // Extract buffer.
        auto buffer = gg::get<std::span<uint8_t>>(payload);
        std::string json_str(reinterpret_cast<const char*>(buffer.data()), buffer.size());
        
        std::cout << "Received command from IoT Core: " << json_str << std::endl;
        
        // Simple JSON parsing for demo.
        std::string command;
        std::string device_id = "device1";  // Default
        
        // Extract command.
        size_t cmd_pos = json_str.find("\"command\":");
        if (cmd_pos != std::string::npos) {
            size_t start = json_str.find("\"", cmd_pos + 10) + 1;
            size_t end = json_str.find("\"", start);
            if (end != std::string::npos) {
                command = json_str.substr(start, end - start);
            }
        }
        
        // Extract device_id if present.
        size_t dev_pos = json_str.find("\"device_id\":");
        if (dev_pos != std::string::npos) {
            size_t start = json_str.find("\"", dev_pos + 12) + 1;
            size_t end = json_str.find("\"", start);
            if (end != std::string::npos) {
                device_id = json_str.substr(start, end - start);
            }
        }
        
        if (!command.empty()) {
            std::lock_guard<std::mutex> lock(command_mutex);
            pending_command = {device_id, command};
            has_pending_command = true;
            command_cv.notify_one();
            
            std::cout << "Received command from cloud: " << command << std::endl;
        }
    }
};

int main() {
    // Disable stdout buffering for real-time logging in systemd/Greengrass.
    std::cout.setf(std::ios::unitbuf);
    
    std::cout << "Device Controller component starting..." << std::endl;
    
    auto& client = gg::ipc::Client::get();
    
    auto error = client.connect();
    if (error) {
        std::cerr << "Failed to connect to Greengrass nucleus: " 
                 << error.message() << std::endl;
        return 1;
    }
    
    std::cout << "Connected to Greengrass IPC" << std::endl;
    
    // Start telemetry publisher thread.
    std::thread telemetry_thread(telemetry_publisher_thread);
    telemetry_thread.detach();
    
    // Subscribe to commands from IoT Core.
    static CloudCommandCallback handler;
    error = client.subscribe_to_iot_core(COMMAND_TOPIC, handler);
    
    if (error) {
        std::cerr << "Failed to subscribe to IoT Core topic: " 
                 << error.message() << std::endl;
        return 1;
    }
    
    std::cout << "Subscribed to " << COMMAND_TOPIC << std::endl;
    std::cout << "Waiting for commands from IoT Core..." << std::endl;
    
    // Keep running.
    while (true) {
        using namespace std::chrono_literals;
        std::this_thread::sleep_for(1s);
    }
    
    return 0;
}
2. Crea e impacchetta il componente

Alcune lingue richiedono la creazione o la creazione di pacchetti prima della distribuzione.

Python

Python non richiede la compilazione. Il componente può utilizzare direttamente il file.py.

Java

Per creare un JAR eseguibile con tutte le dipendenze raggruppate:

  1. Crea un pom.xml file nella directory del tuo progetto:

    <?xml version="1.0" encoding="UTF-8"?>
<project xmlns="http://maven.apache.org/POM/4.0.0"
         xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
         xsi:schemaLocation="http://maven.apache.org/POM/4.0.0 http://maven.apache.org/xsd/maven-4.0.0.xsd">
    <modelVersion>4.0.0</modelVersion>

    <!-- Basic project information: organization, component name, and version -->
    <groupId>com.example</groupId>
    <artifactId>device-controller</artifactId>
    <version>1.0.0</version>

    <properties>
        <!-- Java 11 LTS (Long Term Support) is recommended for Greengrass v2 components -->
        <maven.compiler.source>11</maven.compiler.source>
        <maven.compiler.target>11</maven.compiler.target>
    </properties>

    <dependencies>
        <!-- AWS IoT Device SDK for Java - provides IPC client for Greengrass v2 cloud communication -->
        <dependency>
            <groupId>software.amazon.awssdk.iotdevicesdk</groupId>
            <artifactId>aws-iot-device-sdk</artifactId>
            <version>1.25.1</version>
        </dependency>
    </dependencies>

    <build>
        <plugins>
            <!-- Maven Shade Plugin - creates a standalone JAR with all dependencies included for Greengrass deployment -->
            <plugin>
                <groupId>org.apache.maven.plugins</groupId>
                <artifactId>maven-shade-plugin</artifactId>
                <version>3.2.4</version>
                <executions>
                    <execution>
                        <phase>package</phase>
                        <goals>
                            <goal>shade</goal>
                        </goals>
                        <configuration>
                            <transformers>
                                <!-- Set the main class for the executable JAR -->
                                <transformer implementation="org.apache.maven.plugins.shade.resource.ManifestResourceTransformer">
                                    <mainClass>DeviceController</mainClass>
                                </transformer>
                            </transformers>
                            <filters>
                                <!-- Exclude signature files to avoid security exceptions -->
                                <filter>
                                    <artifact>*:*</artifact>
                                    <excludes>
                                        <exclude>META-INF/*.SF</exclude>
                                        <exclude>META-INF/*.DSA</exclude>
                                        <exclude>META-INF/*.RSA</exclude>
                                    </excludes>
                                </filter>
                            </filters>
                        </configuration>
                    </execution>
                </executions>
            </plugin>
        </plugins>
    </build>
</project>

  2. Costruisci il JAR:

    mvn clean package

    Questo crea target/device-controller-1.0.0.jar con tutte le dipendenze incluse.

  3. Carica il JAR nel tuo bucket S3 per la distribuzione.

JavaScript

Per impacchettare il componente Node.js con tutte le dipendenze:

  1. Crea un package.json file:

    {
  "name": "device-controller",
  "version": "1.0.0",
  "description": "Device controller component for Greengrass v2",
  "main": "DeviceController.js",
  "dependencies": {
    "aws-iot-device-sdk-v2": "^1.21.0"
  },
  "engines": {
    "node": ">=14.0.0"
  }
}

  2. Installa le dipendenze sulla tua macchina di sviluppo:

    npm install

    Questo crea una node_modules cartella contenente la AWS SDK per dispositivi AWS IoT v2.

  3. Package per l'implementazione:

    zip -r DeviceController.zip DeviceController.js node_modules/ package.json

  4. Carica il file zip nel tuo bucket S3 per la distribuzione.

Nota

Sul dispositivo Greengrass deve essere installato il runtime Node.js (versione 14 o successiva). Non è necessario eseguirlo npm install sul dispositivo principale Greengrass poiché l'elemento del componente include tutte le dipendenze nella cartella in bundle. node_modules

C

Prerequisiti:

Per creare l'SDK e il componente, sono necessarie le seguenti dipendenze di compilazione:

  • GCC o Clang

  • CMake (almeno la versione 3.22)

  • Make or Ninja

Installa le dipendenze di compilazione:

Su Ubuntu/Debian:

sudo apt install build-essential cmake

Su Amazon Linux:

sudo yum install gcc cmake make

Crea un CMake file Lists.txt per il tuo componente:

cmake_minimum_required(VERSION 3.10)
project(DeviceController C)

set(CMAKE_C_STANDARD 11)

# Add AWS Greengrass Component SDK
add_subdirectory(aws-greengrass-component-sdk)

# Build your component executable
add_executable(device_controller device_controller.c)
target_link_libraries(device_controller gg-sdk)

Procedura di creazione:

# Clone the AWS Greengrass Component SDK into your project
git clone https://github.com/aws-greengrass/aws-greengrass-component-sdk.git

# Build your component
cmake -B build -D CMAKE_BUILD_TYPE=MinSizeRel
make -C build -j$(nproc)

# The binary 'device_controller' is in ./build/
# Upload this binary to S3 for deployment
C++

Prerequisiti:

Per creare l'SDK e il componente, avrai bisogno delle seguenti dipendenze di compilazione:

  • GCC o Clang con supporto C++20

  • CMake (almeno la versione 3.22)

  • Make or Ninja

Installa le dipendenze di compilazione:

Su Ubuntu/Debian:

sudo apt install build-essential cmake

Su Amazon Linux:

sudo yum install gcc-c++ cmake make

Crea un CMake file Lists.txt per il tuo componente:

cmake_minimum_required(VERSION 3.10)
project(DeviceController CXX)

set(CMAKE_CXX_STANDARD 20)

# Add SDK as subdirectory
add_subdirectory(aws-greengrass-component-sdk)

# Add C++ SDK subdirectory
add_subdirectory(aws-greengrass-component-sdk/cpp)

add_executable(device_controller device_controller.cpp)
target_link_libraries(device_controller gg-sdk++)

Procedura di creazione:

# Clone the AWS Greengrass Component SDK into your project
git clone https://github.com/aws-greengrass/aws-greengrass-component-sdk.git

# Build your component
cmake -B build -D CMAKE_BUILD_TYPE=MinSizeRel
make -C build -j$(nproc)

# The binary 'device_controller' will be in ./build/
# Upload this binary to S3 for deployment
3. Ricetta del componente

Aggiorna l'array «resources» con gli argomenti effettivi utilizzati dal componente.

Python
{
  "RecipeFormatVersion": "2020-01-25",
  "ComponentName": "com.example.DeviceController",
  "ComponentVersion": "1.0.0",
  "ComponentType": "aws.greengrass.generic",
  "ComponentDescription": "Receives commands from IoT Core and sends telemetry back to cloud",
  "ComponentPublisher": "[Your Company]",
  "ComponentConfiguration": {
    "DefaultConfiguration": {
      "accessControl": {
        "aws.greengrass.ipc.mqttproxy": {
          "com.example.DeviceController:mqttproxy:1": {
            "policyDescription": "Allows access to subscribe to IoT Core topics",
            "operations": [
              "aws.greengrass#SubscribeToIoTCore"
            ],
            "resources": [
              "commands/device1"
            ]
          },
          "com.example.DeviceController:mqttproxy:2": {
            "policyDescription": "Allows access to publish to IoT Core topics",
            "operations": [
              "aws.greengrass#PublishToIoTCore"
            ],
            "resources": [
              "telemetry/device1"
            ]
          }
        }
      }
    }
  },
  "ComponentDependencies": {
    "aws.greengrass.TokenExchangeService": {
      "VersionRequirement": ">=2.0.0",
      "DependencyType": "HARD"
    }
  },
  "Manifests": [
    {
      "Platform": {
        "os": "linux",
        "runtime": "*"
      },
      "Lifecycle": {
        "run": "python3 -u {artifacts:path}/device_controller.py"
      },
      "Artifacts": [
        {
          "Uri": "s3://YOUR-BUCKET/artifacts/com.example.DeviceController/1.0.0/device_controller.py"
        }
      ]
    }
  ]
}
Java
{
  "RecipeFormatVersion": "2020-01-25",
  "ComponentName": "com.example.DeviceController",
  "ComponentVersion": "1.0.0",
  "ComponentType": "aws.greengrass.generic",
  "ComponentDescription": "Receives commands from IoT Core and sends telemetry back to cloud",
  "ComponentPublisher": "[Your Company]",
  "ComponentConfiguration": {
    "DefaultConfiguration": {
      "accessControl": {
        "aws.greengrass.ipc.mqttproxy": {
          "com.example.DeviceController:mqttproxy:1": {
            "policyDescription": "Allows access to subscribe to IoT Core topics",
            "operations": [
              "aws.greengrass#SubscribeToIoTCore"
            ],
            "resources": [
              "commands/device1"
            ]
          },
          "com.example.DeviceController:mqttproxy:2": {
            "policyDescription": "Allows access to publish to IoT Core topics",
            "operations": [
              "aws.greengrass#PublishToIoTCore"
            ],
            "resources": [
              "telemetry/device1"
            ]
          }
        }
      }
    }
  },
  "ComponentDependencies": {
    "aws.greengrass.TokenExchangeService": {
      "VersionRequirement": ">=2.0.0",
      "DependencyType": "HARD"
    }
  },
  "Manifests": [
    {
      "Platform": {
        "os": "linux",
        "runtime": "*"
      },
      "Lifecycle": {
        "run": "java -jar {artifacts:path}/DeviceController.jar"
      },
      "Artifacts": [
        {
          "Uri": "s3://YOUR-BUCKET/artifacts/com.example.DeviceController/1.0.0/DeviceController.jar"
        }
      ]
    }
  ]
}
JavaScript
{
  "RecipeFormatVersion": "2020-01-25",
  "ComponentName": "com.example.DeviceController",
  "ComponentVersion": "1.0.0",
  "ComponentType": "aws.greengrass.generic",
  "ComponentDescription": "Receives commands from IoT Core and sends telemetry back to cloud",
  "ComponentPublisher": "[Your Company]",
  "ComponentConfiguration": {
    "DefaultConfiguration": {
      "accessControl": {
        "aws.greengrass.ipc.mqttproxy": {
          "com.example.DeviceController:mqttproxy:1": {
            "policyDescription": "Allows access to subscribe to command topics from IoT Core",
            "operations": [
              "aws.greengrass#SubscribeToIoTCore"
            ],
            "resources": [
              "commands/device1"
            ]
          },
          "com.example.DeviceController:mqttproxy:2": {
            "policyDescription": "Allows access to publish telemetry to IoT Core",
            "operations": [
              "aws.greengrass#PublishToIoTCore"
            ],
            "resources": [
              "telemetry/*"
            ]
          }
        }
      }
    }
  },
  "Manifests": [
    {
      "Platform": {
        "os": "linux",
        "runtime": "*"
      },
      "Lifecycle": {
        "run": "cd {artifacts:decompressedPath}/DeviceController && node DeviceController.js"
      },
      "Artifacts": [
        {
          "Uri": "s3://YOUR-BUCKET/artifacts/com.example.DeviceController/1.0.0/DeviceController.zip",
          "Unarchive": "ZIP"
        }
      ]
    }
  ]
}
C/C++
{
  "RecipeFormatVersion": "2020-01-25",
  "ComponentName": "com.example.DeviceController",
  "ComponentVersion": "1.0.0",
  "ComponentType": "aws.greengrass.generic",
  "ComponentDescription": "Receives commands from IoT Core and sends telemetry back to cloud",
  "ComponentPublisher": "[Your Company]",
  "ComponentConfiguration": {
    "DefaultConfiguration": {
      "accessControl": {
        "aws.greengrass.ipc.mqttproxy": {
          "com.example.DeviceController:mqttproxy:1": {
            "policyDescription": "Allows access to subscribe to IoT Core topics",
            "operations": ["aws.greengrass#SubscribeToIoTCore"],
            "resources": ["commands/device1"]
          },
          "com.example.DeviceController:mqttproxy:2": {
            "policyDescription": "Allows access to publish to IoT Core topics",
            "operations": ["aws.greengrass#PublishToIoTCore"],
            "resources": ["telemetry/device1"]
          }
        }
      }
    }
  },
  "Manifests": [
    {
      "Platform": {
        "os": "linux",
        "runtime": "*"
      },
      "Lifecycle": {
        "run": "{artifacts:path}/device_controller"
      },
      "Artifacts": [
        {
          "Uri": "s3://YOUR-BUCKET/artifacts/com.example.DeviceController/1.0.0/device_controller"
        }
      ]
    }
  ]
}