DZone Spotlight

Java, known for its versatility and robustness, has often faced criticism for its verbosity. However, it's essential to recognize that Java's perceived verbosity is not always a fault of the language itself but can be attributed to overengineering in code design. In this article, we'll explore the benefits of simplifying Java code by reducing unnecessary layers and interfaces and unlocking the power of simplicity for enhanced maintainability without sacrificing functionality. The Pitfall of Unnecessary Interfaces One common practice contributing to code complexity is the creation of interfaces without a clear purpose. Consider the classical case of having one interface for one implementation: Java public interface CreditCard { String payment(); } public class CreditCardImpl implements CreditCard{ String payment(); } The first sign of an unnecessary interface is the generation of a non-meaningful name, going against the principles of Clean Code advocated by Robert Martin. Instead of creating separate interfaces and implementations, a more straightforward approach is to have a single class handling both: Java public class CreditCard { public String payment() { return "Payment done!"; } } By eliminating the unnecessary interface, the code becomes more concise and adheres to the principles of clarity and simplicity. Choosing Interfaces Wisely Interfaces are potent tools in Java, but they should be used judiciously. One valid interface use case is implementing design patterns like the strategy pattern. For instance, you might have various strategies in a payment system, such as credit card payments, debit card payments, and more. In such scenarios, interfaces can help define a common contract: Java public interface Payment { String payment(); } public class CreditCard implements Payment { public String payment() { return "Credit card payment done!"; } } public class DebitCard implements Payment { public String payment() { return "Debit card payment done!"; } } Here, interfaces provide a unified structure for different payment strategies. The Unnecessary Layer Conundrum Another pitfall in code design involves the creation of unnecessary layers that act as mere pass-throughs, adding complexity without offering tangible benefits. Consider a scenario where an additional layer is introduced without any clear purpose: Java public class PaymentGateway { private CreditCard creditCard; public PaymentGateway(CreditCard creditCard) { this.creditCard = creditCard; } public String processPayment() { // Some processing logic return creditCard.payment(); } } In cases where the added layer serves no meaningful purpose, it's advisable to remove it, simplifying the code and improving its clarity: Java public class PaymentProcessor { private CreditCard creditCard; public PaymentProcessor(CreditCard creditCard) { this.creditCard = creditCard; } public String processPayment() { // Processing logic directly in the class return creditCard.payment(); } } Eliminating unnecessary layers makes the code more straightforward to maintain. Embracing Simplicity for Maintainability In conclusion, the key to unlocking the full potential of Java lies in embracing simplicity. Avoid unnecessary interfaces and layers that add complexity without providing clear benefits. Choose interfaces wisely, leveraging them for scenarios that enhance code structure, such as implementing design patterns. By simplifying your Java code, you make it more readable and maintainable, ensuring a more efficient and enjoyable development process. Video

By Otavio Santana CORE

In this article, I will show you how to use Cloudera DataFlow powered by Apache NiFi to interact with IBM WatsonX.AI foundation large language models in real time. We can work with any of the foundation models such as Google FLAN T5 XXL or IBM Granite models. I’ll show you how easy it is to build a real-time data pipeline feeding your Slack-like and mobile applications questions directly to secure WatsonX.AI models running in IBM Cloud. We will handle all the security, management, lineage, and governance with Cloudera Data Flow. As part of decision-making, we can choose different WatsonX.AI models on the fly based on what type of prompt it is. For example, if we want to continue a sentence versus answering a question I can pick different models. For questions answering Google FLAN T5 XXL works well. If I want to continue sentences I would use one of the IBM Granite models. You will notice how amazingly fast the WatsonX.AI models return the results we need. I do some quick enrichment and transformation and then send them out their way to Cloudera Apache Kafka to be used for continuous analytics and distribution to many other applications, systems, platforms, and downstream consumers. We will also output our answers to the original requester which could be someone in a Slack channel or someone in an application. All of this happens in real-time, with no code, full governance, lineage, data management, and security at any scale and on any platform. The power of IBM and Cloudera together in private, public, and hybrid cloud environments for real-time data and AI is just getting started. Try it today. Step By Step Real-Time Flow First, in Slack, I type a question: “Q: What is a good way to integrate Generative AI and Apache NiFi?” NiFi Flow Top Once that question is typed, the Slack server sends these events to our registered service. This can be hosted anywhere publicly facing. (Click here for Slack API link) Slack API Once enabled, your server will start receiving JSON events for each Slack post. This is easy to receive and parse in NiFi. Cloudera DataFlow enables receiving secure HTTPS REST calls in the public cloud-hosted edition with ease, even in Designer mode. NiFi Top Flow 2 In the first part of the flow, we received the REST JSON Post, which is as follows. Slackbot 1.0 (+https://api.slack.com/robots) application/json POST HTTP/1.1 { "token" : "qHvJe59yetAp1bao6wmQzH0C", "team_id" : "T1SD6MZMF", "context_team_id" : "T1SD6MZMF", "context_enterprise_id" : null, "api_app_id" : "A04U64MN9HS", "event" : { "type" : "message", "subtype" : "bot_message", "text" : "==== NiFi to IBM <http://WatsonX.AI|WatsonX.AI> LLM Answers\n\nOn Date: Wed, 15 Nov 20 This is a very rich detailed JSON file that we could push immediately raw to an Apache Iceberg Open Cloud Lakehouse, a Kafka topic, or an object store as a JSON document (Enhancement Option). I am just going to parse what I need. EvaluateJSONPath We parse out the channel ID and plain text of the post. I only want messages from general (“C1SD6N197”). Then I copy the texts to an inputs field as is required for Hugging Face. We check our input: if it’s stocks or weather (more to come) we avoid calling the LLM. SELECT * FROM FLOWFILE WHERE upper(inputs) like '%WEATHER%' AND not upper(inputs) like '%LLM SKIPPED%' SELECT * FROM FLOWFILE WHERE upper(inputs) like '%STOCK%' AND not upper(inputs) like '%LLM SKIPPED%' SELECT * FROM FLOWFILE WHERE (upper(inputs) like 'QUESTION:%' OR upper(inputs) like 'Q:%') and not upper(inputs) like '%WEATHER%' and not upper(inputs) like '%STOCK%' For Stocks processing: To parse what stock we need I am using my Open NLP processor to get it. So you will need to download the processor and the Entity extraction models. GitHub - tspannhw/nifi-nlp-processor: Apache NiFi NLP Processor Open NLP Example Apache NiFi Processor Then we pass that company name to an HTTP REST endpoint from AlphaVantage that converts the Company Name to Stock symbols. In free accounts, you only get a few calls a day, so if we fail we then bypass this step and try to just use whatever you passed in. Using RouteOnContent we filter an Error message out. Then we use a QueryRecord processor to convert from CSV to JSON and filter. SELECT name as companyName, symbol FROM FLOWFILE ORDER BY matchScore DESC LIMIT 1 We do a SplitRecord to ensure we are only one record. We then run EvaluateJsonPath to get our fields as attributes. In an UpdateAttribute we trim the symbol just in case. ${stockSymbol:trim()} We then pass that stock symbol to Twelve Data via InvokeHTTP to get our stock data. We then get a lot of stock data back. { "meta" : { "symbol" : "IBM", "interval" : "1min", "currency" : "USD", "exchange_timezone" : "America/New_York", "exchange" : "NYSE", "mic_code" : "XNYS", "type" : "Common Stock" }, "values" : [ { "datetime" : "2023-11-15 10:37:00", "open" : "152.07001", "high" : "152.08000", "low" : "151.99500", "close" : "152.00999", "volume" : "8525" }, { "datetime" : "2023-11-15 10:36:00", "open" : "152.08501", "high" : "152.12250", "low" : "152.08000", "close" : "152.08501", "volume" : "15204" } ... We then run EvaluateJSONPath to grab the exchange information. We fork the record to just get one record as this is just to return to Slack. We use UpdateRecord calls to enrich the stock data with other values. We then run a QueryRecord to limit us to 1 record to send to Slack. SELECT * FROM FLOWFILE ORDER BY 'datetime' DESC LIMIT 1 We run an EvaluateJsonPath to get the most value fields to display. We then run a PutSlack with our message. LLM Skipped. Stock Value for ${companyName} [${nlp_org_1}/${stockSymbol}] on ${date} is ${closeStockValue}. stock date ${stockdateTime}. stock exchange ${exchange} We also have a separate flow that is split from Company Name. In the first step, we call Yahoo Finance to get RSS headlines for that stock. https://feeds.finance.yahoo.com/rss/2.0/headline?s=${stockSymbol:trim()}&region=US&lang=en-US We use QueryRecord to convert RSS/XML Records to JSON. We then run a SplitJSON to break out the news items. We run a SplitRecord to limit to 1 record. We use EvaluateJSONPath to get the fields we need for our Slack message. We then run UpdateRecord to finalize our JSON. We then send this message to Slack. LLM Skipped. Stock News Information for ${companyName} [${nlp_org_1}/${stockSymbol}] on ${date} ${title} : ${description}. ${guid} article date ${pubdate} For those who selected weather, we follow a similar route (we should add caching with Redis @ Aiven) to stocks. We use my OpenNLP processor to extract locations you might want to have weather on. The next step is taking the output of the processor and building a value to send to our Geoencoder. weatherlocation = ${nlp_location_1:notNull():ifElse(${nlp_location_1}, "New York City")} If we can’t find a valid location, I am going to say “New York City." We could use some other lookup. I am doing some work on loading all locations and could do some advanced PostgreSQL searches on that - or perhaps OpenSearch or a vectorized datastore. I pass that location to Open Meteo to find the geo via InvokeHTTP. https://geocoding-api.open-meteo.com/v1/search?name=${weatherlocation:trim():urlEncode()}&count=1&language=en&format=json We then parse the values we need from the results. { "results" : [ { "id" : 5128581, "name" : "New York", "latitude" : 40.71427, "longitude" : -74.00597, "elevation" : 10.0, "feature_code" : "PPL", "country_code" : "US", "admin1_id" : 5128638, "timezone" : "America/New_York", "population" : 8175133, "postcodes" : [ "10001", "10002", "10003", "10004", "10005", "10006", "10007", "10008", "10009", "10010", "10011", "10012", "10013", "10014", "10016", "10017", "10018", "10019", "10020", "10021", "10022", "10023", "10024", "10025", "10026", "10027", "10028", "10029", "10030", "10031", "10032", "10033", "10034", "10035", "10036", "10037", "10038", "10039", "10040", "10041", "10043", "10044", "10045", "10055", "10060", "10065", "10069", "10080", "10081", "10087", "10090", "10101", "10102", "10103", "10104", "10105", "10106", "10107", "10108", "10109", "10110", "10111", "10112", "10113", "10114", "10115", "10116", "10117", "10118", "10119", "10120", "10121", "10122", "10123", "10124", "10125", "10126", "10128", "10129", "10130", "10131", "10132", "10133", "10138", "10150", "10151", "10152", "10153", "10154", "10155", "10156", "10157", "10158", "10159", "10160", "10161", "10162", "10163", "10164", "10165", "10166", "10167", "10168", "10169", "10170", "10171", "10172", "10173", "10174", "10175", "10176", "10177", "10178", "10179", "10185", "10199", "10203", "10211", "10212", "10213", "10242", "10249", "10256", "10258", "10259", "10260", "10261", "10265", "10268", "10269", "10270", "10271", "10272", "10273", "10274", "10275", "10276", "10277", "10278", "10279", "10280", "10281", "10282", "10285", "10286" ], "country_id" : 6252001, "country" : "United States", "admin1" : "New York" } ], "generationtime_ms" : 0.92196465 } We then parse the results so we can call another API to get the current weather for that latitude and longitude via InvokeHTTP. https://api.weather.gov/points/${latitude:trim()},${longitude:trim()} The results are geo-json. { "@context": [ "https://geojson.org/geojson-ld/geojson-context.jsonld", { "@version": "1.1", "wx": "https://api.weather.gov/ontology#", "s": "https://schema.org/", "geo": "http://www.opengis.net/ont/geosparql#", "unit": "http://codes.wmo.int/common/unit/", "@vocab": "https://api.weather.gov/ontology#", "geometry": { "@id": "s:GeoCoordinates", "@type": "geo:wktLiteral" }, "city": "s:addressLocality", "state": "s:addressRegion", "distance": { "@id": "s:Distance", "@type": "s:QuantitativeValue" }, "bearing": { "@type": "s:QuantitativeValue" }, "value": { "@id": "s:value" }, "unitCode": { "@id": "s:unitCode", "@type": "@id" }, "forecastOffice": { "@type": "@id" }, "forecastGridData": { "@type": "@id" }, "publicZone": { "@type": "@id" }, "county": { "@type": "@id" } } ], "id": "https://api.weather.gov/points/40.7143,-74.006", "type": "Feature", "geometry": { "type": "Point", "coordinates": [ -74.006, 40.714300000000001 ] }, "properties": { "@id": "https://api.weather.gov/points/40.7143,-74.006", "@type": "wx:Point", "cwa": "OKX", "forecastOffice": "https://api.weather.gov/offices/OKX", "gridId": "OKX", "gridX": 33, "gridY": 35, "forecast": "https://api.weather.gov/gridpoints/OKX/33,35/forecast", "forecastHourly": "https://api.weather.gov/gridpoints/OKX/33,35/forecast/hourly", "forecastGridData": "https://api.weather.gov/gridpoints/OKX/33,35", "observationStations": "https://api.weather.gov/gridpoints/OKX/33,35/stations", "relativeLocation": { "type": "Feature", "geometry": { "type": "Point", "coordinates": [ -74.0279259, 40.745251000000003 ] }, "properties": { "city": "Hoboken", "state": "NJ", "distance": { "unitCode": "wmoUnit:m", "value": 3906.1522008034999 }, "bearing": { "unitCode": "wmoUnit:degree_(angle)", "value": 151 } } }, "forecastZone": "https://api.weather.gov/zones/forecast/NYZ072", "county": "https://api.weather.gov/zones/county/NYC061", "fireWeatherZone": "https://api.weather.gov/zones/fire/NYZ212", "timeZone": "America/New_York", "radarStation": "KDIX" } } We use EvaluateJSONPath to grab a forecast URL. Then we call that forecast URL via invokeHTTP. That produces a larger JSON output that we will parse for the results we want to return to Slack. { "@context": [ "https://geojson.org/geojson-ld/geojson-context.jsonld", { "@version": "1.1", "wx": "https://api.weather.gov/ontology#", "geo": "http://www.opengis.net/ont/geosparql#", "unit": "http://codes.wmo.int/common/unit/", "@vocab": "https://api.weather.gov/ontology#" } ], "type": "Feature", "geometry": { "type": "Polygon", "coordinates": [ [ [ -74.025095199999996, 40.727052399999998 ], [ -74.0295579, 40.705361699999997 ], [ -74.000948300000005, 40.701977499999998 ], [ -73.996479800000003, 40.723667899999995 ], [ -74.025095199999996, 40.727052399999998 ] ] ] }, "properties": { "updated": "2023-11-15T14:34:46+00:00", "units": "us", "forecastGenerator": "BaselineForecastGenerator", "generatedAt": "2023-11-15T15:11:39+00:00", "updateTime": "2023-11-15T14:34:46+00:00", "validTimes": "2023-11-15T08:00:00+00:00/P7DT17H", "elevation": { "unitCode": "wmoUnit:m", "value": 2.1335999999999999 }, "periods": [ { "number": 1, "name": "Today", "startTime": "2023-11-15T10:00:00-05:00", "endTime": "2023-11-15T18:00:00-05:00", "isDaytime": true, "temperature": 51, "temperatureUnit": "F", "temperatureTrend": null, "probabilityOfPrecipitation": { "unitCode": "wmoUnit:percent", "value": null }, "dewpoint": { "unitCode": "wmoUnit:degC", "value": 2.2222222222222223 }, "relativeHumidity": { "unitCode": "wmoUnit:percent", "value": 68 }, "windSpeed": "1 to 7 mph", "windDirection": "SW", "icon": "https://api.weather.gov/icons/land/day/bkn?size=medium", "shortForecast": "Partly Sunny", "detailedForecast": "Partly sunny, with a high near 51. Southwest wind 1 to 7 mph." }, { "number": 2, "name": "Tonight", "startTime": "2023-11-15T18:00:00-05:00", "endTime": "2023-11-16T06:00:00-05:00", "isDaytime": false, "temperature": 44, "temperatureUnit": "F", "temperatureTrend": null, "probabilityOfPrecipitation": { "unitCode": "wmoUnit:percent", "value": null }, "dewpoint": { "unitCode": "wmoUnit:degC", "value": 3.8888888888888888 }, "relativeHumidity": { "unitCode": "wmoUnit:percent", "value": 82 }, "windSpeed": "8 mph", "windDirection": "SW", "icon": "https://api.weather.gov/icons/land/night/sct?size=medium", "shortForecast": "Partly Cloudy", "detailedForecast": "Partly cloudy, with a low around 44. Southwest wind around 8 mph." }, { "number": 3, "name": "Thursday", "startTime": "2023-11-16T06:00:00-05:00", "endTime": "2023-11-16T18:00:00-05:00", "isDaytime": true, "temperature": 60, "temperatureUnit": "F", "temperatureTrend": "falling", "probabilityOfPrecipitation": { "unitCode": "wmoUnit:percent", "value": null }, "dewpoint": { "unitCode": "wmoUnit:degC", "value": 5.5555555555555554 }, "relativeHumidity": { "unitCode": "wmoUnit:percent", "value": 82 }, "windSpeed": "6 mph", "windDirection": "SW", "icon": "https://api.weather.gov/icons/land/day/few?size=medium", "shortForecast": "Sunny", "detailedForecast": "Sunny. High near 60, with temperatures falling to around 58 in the afternoon. Southwest wind around 6 mph." }, { "number": 4, "name": "Thursday Night", "startTime": "2023-11-16T18:00:00-05:00", "endTime": "2023-11-17T06:00:00-05:00", "isDaytime": false, "temperature": 47, "temperatureUnit": "F", "temperatureTrend": null, "probabilityOfPrecipitation": { "unitCode": "wmoUnit:percent", "value": null }, "dewpoint": { "unitCode": "wmoUnit:degC", "value": 6.1111111111111107 }, "relativeHumidity": { "unitCode": "wmoUnit:percent", "value": 80 }, "windSpeed": "3 mph", "windDirection": "SW", "icon": "https://api.weather.gov/icons/land/night/few?size=medium", "shortForecast": "Mostly Clear", "detailedForecast": "Mostly clear, with a low around 47. Southwest wind around 3 mph." }, { "number": 5, "name": "Friday", "startTime": "2023-11-17T06:00:00-05:00", "endTime": "2023-11-17T18:00:00-05:00", "isDaytime": true, "temperature": 63, "temperatureUnit": "F", "temperatureTrend": "falling", "probabilityOfPrecipitation": { "unitCode": "wmoUnit:percent", "value": 20 }, "dewpoint": { "unitCode": "wmoUnit:degC", "value": 12.222222222222221 }, "relativeHumidity": { "unitCode": "wmoUnit:percent", "value": 86 }, "windSpeed": "2 to 10 mph", "windDirection": "S", "icon": "https://api.weather.gov/icons/land/day/bkn/rain,20?size=medium", "shortForecast": "Partly Sunny then Slight Chance Light Rain", "detailedForecast": "A slight chance of rain after 1pm. Partly sunny. High near 63, with temperatures falling to around 61 in the afternoon. South wind 2 to 10 mph. Chance of precipitation is 20%." }, { "number": 6, "name": "Friday Night", "startTime": "2023-11-17T18:00:00-05:00", "endTime": "2023-11-18T06:00:00-05:00", "isDaytime": false, "temperature": 51, "temperatureUnit": "F", "temperatureTrend": null, "probabilityOfPrecipitation": { "unitCode": "wmoUnit:percent", "value": 70 }, "dewpoint": { "unitCode": "wmoUnit:degC", "value": 12.777777777777779 }, "relativeHumidity": { "unitCode": "wmoUnit:percent", "value": 100 }, "windSpeed": "6 to 10 mph", "windDirection": "SW", "icon": "https://api.weather.gov/icons/land/night/rain,60/rain,70?size=medium", "shortForecast": "Light Rain Likely", "detailedForecast": "Rain likely. Cloudy, with a low around 51. Chance of precipitation is 70%. New rainfall amounts between a quarter and half of an inch possible." }, { "number": 7, "name": "Saturday", "startTime": "2023-11-18T06:00:00-05:00", "endTime": "2023-11-18T18:00:00-05:00", "isDaytime": true, "temperature": 55, "temperatureUnit": "F", "temperatureTrend": null, "probabilityOfPrecipitation": { "unitCode": "wmoUnit:percent", "value": 70 }, "dewpoint": { "unitCode": "wmoUnit:degC", "value": 11.111111111111111 }, "relativeHumidity": { "unitCode": "wmoUnit:percent", "value": 100 }, "windSpeed": "8 to 18 mph", "windDirection": "NW", "icon": "https://api.weather.gov/icons/land/day/rain,70/rain,30?size=medium", "shortForecast": "Light Rain Likely", "detailedForecast": "Rain likely before 1pm. Partly sunny, with a high near 55. Chance of precipitation is 70%." }, { "number": 8, "name": "Saturday Night", "startTime": "2023-11-18T18:00:00-05:00", "endTime": "2023-11-19T06:00:00-05:00", "isDaytime": false, "temperature": 40, "temperatureUnit": "F", "temperatureTrend": null, "probabilityOfPrecipitation": { "unitCode": "wmoUnit:percent", "value": null }, "dewpoint": { "unitCode": "wmoUnit:degC", "value": 1.1111111111111112 }, "relativeHumidity": { "unitCode": "wmoUnit:percent", "value": 65 }, "windSpeed": "12 to 17 mph", "windDirection": "NW", "icon": "https://api.weather.gov/icons/land/night/few?size=medium", "shortForecast": "Mostly Clear", "detailedForecast": "Mostly clear, with a low around 40." }, { "number": 9, "name": "Sunday", "startTime": "2023-11-19T06:00:00-05:00", "endTime": "2023-11-19T18:00:00-05:00", "isDaytime": true, "temperature": 50, "temperatureUnit": "F", "temperatureTrend": null, "probabilityOfPrecipitation": { "unitCode": "wmoUnit:percent", "value": null }, "dewpoint": { "unitCode": "wmoUnit:degC", "value": -0.55555555555555558 }, "relativeHumidity": { "unitCode": "wmoUnit:percent", "value": 65 }, "windSpeed": "10 to 14 mph", "windDirection": "W", "icon": "https://api.weather.gov/icons/land/day/few?size=medium", "shortForecast": "Sunny", "detailedForecast": "Sunny, with a high near 50." }, { "number": 10, "name": "Sunday Night", "startTime": "2023-11-19T18:00:00-05:00", "endTime": "2023-11-20T06:00:00-05:00", "isDaytime": false, "temperature": 38, "temperatureUnit": "F", "temperatureTrend": null, "probabilityOfPrecipitation": { "unitCode": "wmoUnit:percent", "value": null }, "dewpoint": { "unitCode": "wmoUnit:degC", "value": -0.55555555555555558 }, "relativeHumidity": { "unitCode": "wmoUnit:percent", "value": 67 }, "windSpeed": "13 mph", "windDirection": "NW", "icon": "https://api.weather.gov/icons/land/night/few?size=medium", "shortForecast": "Mostly Clear", "detailedForecast": "Mostly clear, with a low around 38." }, { "number": 11, "name": "Monday", "startTime": "2023-11-20T06:00:00-05:00", "endTime": "2023-11-20T18:00:00-05:00", "isDaytime": true, "temperature": 46, "temperatureUnit": "F", "temperatureTrend": null, "probabilityOfPrecipitation": { "unitCode": "wmoUnit:percent", "value": null }, "dewpoint": { "unitCode": "wmoUnit:degC", "value": -1.6666666666666667 }, "relativeHumidity": { "unitCode": "wmoUnit:percent", "value": 70 }, "windSpeed": "13 mph", "windDirection": "NW", "icon": "https://api.weather.gov/icons/land/day/sct?size=medium", "shortForecast": "Mostly Sunny", "detailedForecast": "Mostly sunny, with a high near 46." }, { "number": 12, "name": "Monday Night", "startTime": "2023-11-20T18:00:00-05:00", "endTime": "2023-11-21T06:00:00-05:00", "isDaytime": false, "temperature": 38, "temperatureUnit": "F", "temperatureTrend": null, "probabilityOfPrecipitation": { "unitCode": "wmoUnit:percent", "value": null }, "dewpoint": { "unitCode": "wmoUnit:degC", "value": -1.1111111111111112 }, "relativeHumidity": { "unitCode": "wmoUnit:percent", "value": 70 }, "windSpeed": "10 mph", "windDirection": "N", "icon": "https://api.weather.gov/icons/land/night/sct?size=medium", "shortForecast": "Partly Cloudy", "detailedForecast": "Partly cloudy, with a low around 38." }, { "number": 13, "name": "Tuesday", "startTime": "2023-11-21T06:00:00-05:00", "endTime": "2023-11-21T18:00:00-05:00", "isDaytime": true, "temperature": 49, "temperatureUnit": "F", "temperatureTrend": null, "probabilityOfPrecipitation": { "unitCode": "wmoUnit:percent", "value": 30 }, "dewpoint": { "unitCode": "wmoUnit:degC", "value": 2.7777777777777777 }, "relativeHumidity": { "unitCode": "wmoUnit:percent", "value": 73 }, "windSpeed": "9 to 13 mph", "windDirection": "E", "icon": "https://api.weather.gov/icons/land/day/bkn/rain,30?size=medium", "shortForecast": "Partly Sunny then Chance Light Rain", "detailedForecast": "A chance of rain after 1pm. Partly sunny, with a high near 49. Chance of precipitation is 30%." }, { "number": 14, "name": "Tuesday Night", "startTime": "2023-11-21T18:00:00-05:00", "endTime": "2023-11-22T06:00:00-05:00", "isDaytime": false, "temperature": 46, "temperatureUnit": "F", "temperatureTrend": null, "probabilityOfPrecipitation": { "unitCode": "wmoUnit:percent", "value": 50 }, "dewpoint": { "unitCode": "wmoUnit:degC", "value": 7.7777777777777777 }, "relativeHumidity": { "unitCode": "wmoUnit:percent", "value": 86 }, "windSpeed": "13 to 18 mph", "windDirection": "S", "icon": "https://api.weather.gov/icons/land/night/rain,50?size=medium", "shortForecast": "Chance Light Rain", "detailedForecast": "A chance of rain. Mostly cloudy, with a low around 46. Chance of precipitation is 50%." } ] } } We parse the data with EvaluateJSONPath to get primary fields for the weather. We then format those fields to PutSlack. LLM Skipped. Read forecast on ${date} for ${weatherlocation} @ ${latitude},${longitude} Used ${forecasturl} ${icon} Temp: ${temperature} ${temperatureunit} - ${temperaturetrend} There is a wind ${winddirection} at ${windspeed}. ${detailedforecast} Slack Output If we do have an LLM question, let’s make sure it’s just one record. We use a few different models that are available at IBM WatsonX.AI on IBM Cloud to quickly be accessed by our REST prompts. I tested and built the prompts initially at IBM’s Prompt Lab and then copied the initial curl statement from there. Click here for supported foundation models available with IBM watsonx.ai. ibm/mpt-7b-instruct2meta-llama/llama-2–70b-chatibm/granite-13b-chat-v1 We have to send our unique secure key to IBM and they will give us a token to use in our next call. We parse out the question and then send it to WatsonX via REST API. We build a prompt to send to IBM as follows. { "model_id": "meta-llama/llama-2-70b-chat", "input": "${inputs:urlEncode()}", "parameters": { "decoding_method": "greedy", "max_new_tokens": 200, "min_new_tokens": 50, "stop_sequences": [], "repetition_penalty": 1 }, "project_id": "0ead8ec4-d137-4f9c-8956-50b0da4a7068" } We parse the generated text which is our Generative AI results plus some helpful metadata on timings. The result posted to Slack is as follows: “You can use Apache NiFi to integrate Generative AI models in several ways: Data Preprocessing: Use NiFi to preprocess data before feeding it into your Generative AI model. This can include data cleaning, transformation, and feature engineering. Model Training: Use NiFi to automate the training process of your Generative AI model. You can use NiFi’s PutFile and PutFile_SFTP processors to write the training data to a file, and then use a processor like ExecuteScript to run the training script. Model Deployment: Once your Generative AI model is trained, you can use NiFi to deploy it. You can create a NiFi flow that takes in input data, runs it through the Generative AI model, and then outputs the generated data. Real-time Inference: You can use NiFi’s StreamingJobs” After the Slackbot posted the results, it posted metrics and debugging information to the chat channel. All of the metadata is posted to another Slack channel for administrator monitoring. ==== NiFi to IBM WatsonX.AI LLM Answers On Date: Wed, 15 Nov 2023 15:43:29 GMT Created: 2023-11-15T15:43:29.248Z Prompt: Q: What is a good way to integrate Generative AI and Apache NiFi? Response: ) You can use Apache NiFi to integrate Generative AI models in several ways: 1. Data Preprocessing: Use NiFi to preprocess data before feeding it into your Generative AI model. This can include data cleaning, transformation, and feature engineering. 2. Model Training: Use NiFi to automate the training process of your Generative AI model. You can use NiFi's PutFile and PutFile_SFTP processors to write the training data to a file, and then use a processor like ExecuteScript to run the training script. 3. Model Deployment: Once your Generative AI model is trained, you can use NiFi to deploy it. You can create a NiFi flow that takes in input data, runs it through the Generative AI model, and then outputs the generated data. 4. Real-time Inference: You can use NiFi's StreamingJobs Token: 200 Req Duration: 8153 HTTP TX ID: 89d71099-da23-4e7e-89f9-4e8f5620c0fb IBM Msg: This model is a Non-IBM Product governed by a third-party license that may impose use restrictions and other obligations. By using this model you agree to its terms as identified in the following URL. URL: https://dataplatform.cloud.ibm.com/docs/content/wsj/analyze-data/fm-models.html?context=wx IBM Msg ID: disclaimer_warning Model ID: meta-llama/llama-2-70b-chat Stop Reason: max_tokens Token Count: 38 TX ID: NGp0djg-c05f740f84f84b7c80f93f9da05aa756 UUID: da0806cb-6133-4bf4-808e-1fbf419c09e3 Corr ID: NGp0djg-c05f740f84f84b7c80f93f9da05aa756 Global TX ID: 20c3a9cf276c38bcdaf26e3c27d0479b Service Time: 478 Request ID: 03c2726a-dcb6-407f-96f1-f83f20fe9c9c File Name: 1a3c4386-86d2-4969-805b-37649c16addb Request Duration: 8153 Request URL: https://us-south.ml.cloud.ibm.com/ml/v1-beta/generation/text?version=2023-05-29 cf-ray: 82689bfd28e48ce2-EWR ===== Make Your Own Slackbot Slack Output Kafka Distribute Apache Flink SQL Table Creation DDL CREATE TABLE `ssb`.`Meetups`.`watsonairesults` ( `date` VARCHAR(2147483647), `x_global_transaction_id` VARCHAR(2147483647), `x_request_id` VARCHAR(2147483647), `cf_ray` VARCHAR(2147483647), `inputs` VARCHAR(2147483647), `created_at` VARCHAR(2147483647), `stop_reason` VARCHAR(2147483647), `x_correlation_id` VARCHAR(2147483647), `x_proxy_upstream_service_time` VARCHAR(2147483647), `message_id` VARCHAR(2147483647), `model_id` VARCHAR(2147483647), `invokehttp_request_duration` VARCHAR(2147483647), `message` VARCHAR(2147483647), `uuid` VARCHAR(2147483647), `generated_text` VARCHAR(2147483647), `transaction_id` VARCHAR(2147483647), `tokencount` VARCHAR(2147483647), `generated_token` VARCHAR(2147483647), `ts` VARCHAR(2147483647), `advisoryId` VARCHAR(2147483647), `eventTimeStamp` TIMESTAMP(3) WITH LOCAL TIME ZONE METADATA FROM 'timestamp', WATERMARK FOR `eventTimeStamp` AS `eventTimeStamp` - INTERVAL '3' SECOND ) WITH ( 'deserialization.failure.policy' = 'ignore_and_log', 'properties.request.timeout.ms' = '120000', 'format' = 'json', 'properties.bootstrap.servers' = 'kafka:9092', 'connector' = 'kafka', 'properties.transaction.timeout.ms' = '900000', 'topic' = 'watsonxaillmanswers', 'scan.startup.mode' = 'group-offsets', 'properties.auto.offset.reset' = 'earliest', 'properties.group.id' = 'watsonxaillmconsumer' ) CREATE TABLE `ssb`.`Meetups`.`watsonxresults` ( `date` VARCHAR(2147483647), `x_global_transaction_id` VARCHAR(2147483647), `x_request_id` VARCHAR(2147483647), `cf_ray` VARCHAR(2147483647), `inputs` VARCHAR(2147483647), `created_at` VARCHAR(2147483647), `stop_reason` VARCHAR(2147483647), `x_correlation_id` VARCHAR(2147483647), `x_proxy_upstream_service_time` VARCHAR(2147483647), `message_id` VARCHAR(2147483647), `model_id` VARCHAR(2147483647), `invokehttp_request_duration` VARCHAR(2147483647), `message` VARCHAR(2147483647), `uuid` VARCHAR(2147483647), `generated_text` VARCHAR(2147483647), `transaction_id` VARCHAR(2147483647), `tokencount` VARCHAR(2147483647), `generated_token` VARCHAR(2147483647), `ts` VARCHAR(2147483647), `eventTimeStamp` TIMESTAMP(3) WITH LOCAL TIME ZONE METADATA FROM 'timestamp', WATERMARK FOR `eventTimeStamp` AS `eventTimeStamp` - INTERVAL '3' SECOND ) WITH ( 'deserialization.failure.policy' = 'ignore_and_log', 'properties.request.timeout.ms' = '120000', 'format' = 'json', 'properties.bootstrap.servers' = 'kafka:9092', 'connector' = 'kafka', 'properties.transaction.timeout.ms' = '900000', 'topic' = 'watsonxaillm', 'scan.startup.mode' = 'group-offsets', 'properties.auto.offset.reset' = 'earliest', 'properties.group.id' = 'allwatsonx1' ) Example Prompt {"inputs":"Please answer to the following question. What is the capital of the United States?"} IBM DB2 SQL alter table "DB2INST1"."TRAVELADVISORY" add column "summary" VARCHAR(2048); -- DB2INST1.TRAVELADVISORY definition CREATE TABLE "DB2INST1"."TRAVELADVISORY" ( "TITLE" VARCHAR(250 OCTETS) , "PUBDATE" VARCHAR(250 OCTETS) , "LINK" VARCHAR(250 OCTETS) , "GUID" VARCHAR(250 OCTETS) , "ADVISORYID" VARCHAR(250 OCTETS) , "DOMAIN" VARCHAR(250 OCTETS) , "CATEGORY" VARCHAR(4096 OCTETS) , "DESCRIPTION" VARCHAR(4096 OCTETS) , "UUID" VARCHAR(250 OCTETS) NOT NULL , "TS" BIGINT NOT NULL , "summary" VARCHAR(2048 OCTETS) ) IN "IBMDB2SAMPLEREL" ORGANIZE BY ROW; ALTER TABLE "DB2INST1"."TRAVELADVISORY" ADD PRIMARY KEY ("UUID") ENFORCED; GRANT CONTROL ON TABLE "DB2INST1"."TRAVELADVISORY" TO USER "DB2INST1"; GRANT CONTROL ON INDEX "SYSIBM "."SQL230620142604860" TO USER "DB2INST1"; SELECT "summary", TITLE , ADVISORYID , TS, PUBDATE FROM DB2INST1.TRAVELADVISORY t WHERE "summary" IS NOT NULL ORDER BY ts DESC Example Output Email GitHub README GitHub repo Video Source Code Source Code

By Tim Spann CORE

In today's world of distributed systems and microservices, it is crucial to maintain consistency. Microservice architecture is considered almost a standard for building modern, flexible, and reliable high-loaded systems. But at the same time introduces additional complexities. Monolith vs Microservices In monolithic applications, consistency can be achieved using transactions. Within a transaction, we can modify data in multiple tables. If an error occurred during the modification process, the transaction would roll back and the data would remain consistent. Thus consistency was achieved by the database tools. In a microservice architecture, things get much more complicated. At some point, we will have to change data not only in the current microservice but also in other microservices. Imagine a scenario where a user interacts with a web application and creates an order on the website. When the order is created, it is necessary to reduce the number of items in stock. In a monolithic application, this could look like the following: In a microservice architecture, such tables can change within different microservices. When creating an order, we need to call another service using, for example, REST or Kafka. But there are many problems here: the request may fail, the network or the microservice may be temporarily unavailable, the microservice may stop immediately after creating a record in the orders table and the message will not be sent, etc. Transactional Outbox One solution to this problem is to use the transactional outbox pattern. We can create an order and a record in the outbox table within one transaction, where we will add all the necessary data for a future event. A specific handler will read this record and send the event to another microservice. This way we ensure that the event will be sent if we have successfully created an order. If the network or microservice is unavailable, then the handler will keep trying to send the message until it receives a successful response. This will result in eventual consistency. It is worth noting here that it is necessary to support idempotency because, in such architectures, request processing may be duplicated. Implementation Let's consider an example of implementation in a Spring Boot application. We will use a ready solution transaction-outbox. First, let's start PostgreSQL in Docker: Shell docker run -d -p 5432:5432 --name db \ -e POSTGRES_USER=admin \ -e POSTGRES_PASSWORD=password \ -e POSTGRES_DB=demo \ postgres:12-alpine Add a dependency to build.gradle: Groovy implementation 'com.gruelbox:transactionoutbox-spring:5.3.370' Declare the configuration: Java @Configuration @EnableScheduling @Import({ SpringTransactionOutboxConfiguration.class }) public class TransactionOutboxConfig { @Bean public TransactionOutbox transactionOutbox(SpringTransactionManager springTransactionManager, SpringInstantiator springInstantiator) { return TransactionOutbox.builder() .instantiator(springInstantiator) .initializeImmediately(true) .retentionThreshold(Duration.ofMinutes(5)) .attemptFrequency(Duration.ofSeconds(30)) .blockAfterAttempts(5) .transactionManager(springTransactionManager) .persistor(Persistor.forDialect(Dialect.POSTGRESQL_9)) .build(); } } Here we specify how many attempts should be made in case of unsuccessful request sending, the interval between attempts, etc. For the functioning of a separate thread that will parse records from the outbox table, we need to call outbox.flush() periodically. For this purpose, let's declare a component: Java @Component @AllArgsConstructor public class TransactionOutboxWorker { private final TransactionOutbox transactionOutbox; @Scheduled(fixedDelay = 5000) public void flushTransactionOutbox() { transactionOutbox.flush(); } } The execution time of flush should be chosen according to your requirements. Now we can implement the method with business logic. We need to create an Order in the database and send the event to another microservice. For demonstration purposes, I will not implement the actual call but will simulate the error of sending the event by throwing an exception. The method itself should be marked @Transactional, and the event sending should be done not directly, but using the TransactionOutbox object: Java @Service @AllArgsConstructor @Slf4j public class OrderService { private OrderRepository repository; private TransactionOutbox outbox; @Transactional public String createOrderAndSendEvent(Integer productId, Integer quantity) { String uuid = UUID.randomUUID().toString(); repository.save(new OrderEntity(uuid, productId, quantity)); outbox.schedule(getClass()).sendOrderEvent(uuid, productId, quantity); return uuid; } void sendOrderEvent(String uuid, Integer productId, Integer quantity) { log.info(String.format("Sending event for %s...", uuid)); if (ThreadLocalRandom.current().nextBoolean()) throw new RuntimeException(); log.info(String.format("Event sent for %s", uuid)); } } Here randomly the method may throw an exception. However, the key feature is that this method is not called directly, and the call information is stored in the Outbox table within a single transaction. Let's start the service and execute the query: Shell curl --header "Content-Type: application/json" \ --request POST \ --data '{"productId":"10","quantity":"2"}' \ http://localhost:8080/order {"id":"6a8e2960-8e94-463b-90cb-26ce8b46e96c"} If the method is successful, the record is removed from the table, but if there is a problem, we can see the record in the table: Shell docker exec -ti <CONTAINER ID> bash psql -U admin demo psql (12.16) Type "help" for help. demo=# \x Expanded display is on. demo=# SELECT * FROM txno_outbox; -[ RECORD 1 ]---+------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------ id | d0b69f7b-943a-44c9-9e71-27f738161c8e invocation | {"c":"orderService","m":"sendOrderEvent","p":["String","Integer","Integer"],"a":[{"t":"String","v":"6a8e2960-8e94-463b-90cb-26ce8b46e96c"},{"t":"Integer","v":10},{"t":"Integer","v":2}]} nextattempttime | 2023-11-19 17:59:12.999 attempts | 1 blocked | f version | 1 uniquerequestid | processed | f lastattempttime | 2023-11-19 17:58:42.999515 Here we can see the parameters of the method call, the time of the next attempt, the number of attempts, etc. According to your settings, the handler will try to execute the request until it succeeds or until it reaches the limit of attempts. This way, even if our service restarts (which is considered normal for cloud-native applications), we will not lose important data about the external service call, and eventually the message will be delivered to the recipient. Conclusion Transactional outbox is a powerful solution for addressing data consistency issues in distributed systems. It provides a reliable and organized approach to managing transactions between microservices. This greatly reduces the risks associated with data inconsistency. We have examined the fundamental principles of the transactional outbox pattern, its implementation, and its benefits in maintaining a coherent and synchronized data state. The project code is available on GitHub.

In the dynamic landscape of web development, the choice of an API technology plays a pivotal role in determining the success and efficiency of a project. In this article, we embark on a comprehensive exploration of three prominent contenders: REST, gRPC, and GraphQL. Each of these technologies brings its own set of strengths and capabilities to the table, catering to different use cases and development scenarios. What Is REST? REST API, or Representational State Transfer Application Programming Interface, is a set of architectural principles and conventions for building web services. It provides a standardized way for different software applications to communicate with each other over the Internet. REST is often used in the context of web development to create scalable and maintainable APIs that can be easily consumed by a variety of clients, such as web browsers or mobile applications. Key characteristics of a REST API include: Statelessness: Each request from a client to a server contains all the information needed to understand and process the request. The server does not store any information about the client's state between requests. This enhances scalability and simplifies the implementation on both the client and server sides. Resource-based: REST APIs are centered around resources, which are identified by URLs (Uniform Resource Locators). These resources can represent entities like objects, data, or services. CRUD (Create, Read, Update, Delete) operations are performed on these resources using standard HTTP methods like GET, POST, PUT, and DELETE. Representation: Resources are represented in a format such as JSON (JavaScript Object Notation) or XML (eXtensible Markup Language). Clients can request different representations of a resource, and the server will respond with the data in the requested format. Uniform interface: REST APIs maintain a uniform interface, making it easy for developers to understand and work with different APIs. This uniformity is achieved through a set of constraints, including statelessness, resource-based representation, and standard HTTP methods. Stateless communication: Communication between the client and server is stateless, meaning that each request from the client contains all the information necessary for the server to fulfill that request. The server does not store any information about the client's state between requests. Client-server architecture: REST APIs follow a client-server architecture, where the client and server are independent entities that communicate over a network. This separation allows for flexibility and scalability, as changes to one component do not necessarily affect the other. Cacheability: Responses from the server can be explicitly marked as cacheable or non-cacheable, allowing clients to optimize performance by caching responses when appropriate. REST APIs are widely used in web development due to their simplicity, scalability, and compatibility with the HTTP protocol. They are commonly employed to enable communication between different components of a web application, including front-end clients and back-end servers, or to facilitate integration between different software systems. Pros and Cons of REST REST has several advantages that contribute to its widespread adoption in web development. One key advantage is its simplicity, as RESTful APIs are easy to understand and implement. This simplicity accelerates the development process and facilitates integration between different components of a system. The statelessness of RESTful communication allows for easy scalability, as each request from the client contains all the necessary information, and servers don't need to maintain client state between requests. REST's flexibility, compatibility with various data formats (commonly JSON), and support for caching enhance its overall performance. Its well-established nature and support from numerous tools and frameworks make REST a popular and accessible choice for building APIs. However, REST does come with certain disadvantages. One notable challenge is the potential for over-fetching or under-fetching of data, where clients may receive more information than needed or insufficient data, leading to additional requests. The lack of flexibility in data retrieval, especially in scenarios where clients require specific data combinations, can result in inefficiencies. Additionally, while REST is excellent for stateless communication, it lacks built-in support for real-time features, requiring developers to implement additional technologies or workarounds for immediate data updates. Despite these limitations, the advantages of simplicity, scalability, and widespread support make REST a robust choice for many web development projects. What Is gPRC? gRPC, which stands for "gRPC Remote Procedure Calls," is an open-source RPC (Remote Procedure Call) framework developed by Google. It uses HTTP/2 as its transport protocol and Protocol Buffers (protobuf) as the interface description language. gRPC facilitates communication between client and server applications, allowing them to invoke methods on each other as if they were local procedures, making it a powerful tool for building efficient and scalable distributed systems. Key features of gRPC include: Performance: gRPC is designed to be highly efficient, leveraging the capabilities of HTTP/2 for multiplexing multiple requests over a single connection. It also uses Protocol Buffers, a binary serialization format, which results in faster and more compact data transmission compared to traditional text-based formats like JSON. Language agnostic: gRPC supports multiple programming languages, enabling developers to build applications in languages such as Java, C++, Python, Go, Ruby, and more. This language-agnostic nature promotes interoperability between different components of a system. IDL (Interface Definition Language): gRPC uses Protocol Buffers as its IDL for defining the service methods and message types exchanged between the client and server. This provides a clear and structured way to define APIs, allowing for automatic code generation in various programming languages. Bidirectional streaming: One of gRPC's notable features is its support for bidirectional streaming. This means that both the client and server can send a stream of messages to each other over a single connection, providing flexibility in communication patterns. Code generation: gRPC generates client and server code based on the service definition written in Protocol Buffers. This automatic code generation simplifies the development process and ensures that the client and server interfaces are in sync. Strong typing: gRPC uses strongly typed messages and service definitions, reducing the chances of runtime errors, and making the communication between services more robust. Support for authentication and authorization: gRPC supports various authentication mechanisms, including SSL/TLS for secure communication. It also allows for the implementation of custom authentication and authorization mechanisms. gRPC is particularly well-suited for scenarios where high performance, scalability, and efficient communication between distributed systems are critical, such as in microservices architectures. Its use of modern protocols and technologies makes it a compelling choice for building complex and scalable applications. Pros and Cons of gPRC gRPC presents several advantages that contribute to its popularity in modern distributed systems. One key strength is its efficiency, as it utilizes the HTTP/2 protocol, enabling multiplexing of multiple requests over a single connection and reducing latency. This efficiency, combined with the use of Protocol Buffers for serialization, results in faster and more compact data transmission compared to traditional REST APIs, making gRPC well-suited for high-performance applications. The language-agnostic nature of gRPC allows developers to work with their preferred programming languages, promoting interoperability in heterogeneous environments. The inclusion of bidirectional streaming and strong typing through Protocol Buffers further enhances its capabilities, offering flexibility and reliability in communication between client and server components. While gRPC offers substantial advantages, it comes with certain challenges. One notable drawback is the learning curve associated with adopting gRPC, particularly for teams unfamiliar with Protocol Buffers and the concept of remote procedure calls. Debugging gRPC services can be more challenging due to the binary nature of Protocol Buffers, requiring specialized tools and knowledge for effective troubleshooting. Additionally, the maturity of the gRPC ecosystem may vary across different languages and platforms, potentially impacting the availability of third-party libraries and community support. Integrating gRPC into existing systems or environments that do not fully support HTTP/2 may pose compatibility challenges, requiring careful consideration before migration. Despite these challenges, the efficiency, flexibility, and performance benefits make gRPC a compelling choice for certain types of distributed systems. What Is GraphQL? GraphQL is a query language for APIs (Application Programming Interfaces) and a runtime for executing those queries with existing data. It was developed by Facebook in 2012 and later open-sourced in 2015. GraphQL provides a more efficient, powerful, and flexible alternative to traditional REST APIs by allowing clients to request only the specific data they need. Key features of GraphQL include: Declarative data fetching: Clients can specify the structure of the response they need, including nested data and relationships, in a single query. This eliminates over-fetching and under-fetching of data, ensuring that clients precisely receive the information they request. Single endpoint: GraphQL APIs typically expose a single endpoint, consolidating multiple RESTful endpoints into one. This simplifies the API surface and allows clients to request all the required data in a single query. Strong typing and schema: GraphQL APIs are defined by a schema that specifies the types of data that can be queried and the relationships between them. This schema provides a clear contract between clients and servers, enabling strong typing and automatic validation of queries. Real-time updates (subscriptions): GraphQL supports real-time data updates through a feature called subscriptions. Clients can subscribe to specific events, and the server will push updates to the client when relevant data changes. Introspection: GraphQL APIs are self-documenting. Clients can query the schema itself to discover the types, fields, and relationships available in the API, making it easier to explore and understand the data model. Batched queries: Clients can send multiple queries in a single request, reducing the number of network requests and improving efficiency. Backend aggregation: GraphQL allows the backend to aggregate data from multiple sources, such as databases, microservices, or third-party APIs, and present it to the client in a unified way. GraphQL is often used in modern web development, particularly in single-page applications (SPAs) and mobile apps, where optimizing data transfer and minimizing over-fetching are crucial. It has gained widespread adoption and is supported by various programming languages and frameworks, both on the client and server sides. Deciding the Right API Technology Choosing between REST, gRPC, and GraphQL depends on the specific requirements and characteristics of your project. Each technology has its strengths and weaknesses, making them more suitable for certain use cases. Here are some considerations for when to choose REST, gRPC, or GraphQL: Choose REST when: Simplicity is key: REST is straightforward and easy to understand. If your project requires a simple and intuitive API, REST might be the better choice. Statelessness is sufficient: If statelessness aligns well with your application's requirements and you don't need advanced features like bidirectional streaming, REST is a good fit. Widespread adoption and compatibility: If you need broad compatibility with various clients, platforms, and tooling, REST is well-established and widely supported. Choose gRPC when: High performance is critical: gRPC is designed for high-performance communication, making it suitable for scenarios where low latency and efficient data transfer are crucial, such as microservices architectures. Strong typing is important: If you value strong typing and automatic code generation for multiple programming languages, gRPC's use of Protocol Buffers can be a significant advantage. Bidirectional streaming is needed: For applications that require bidirectional streaming, real-time updates, and efficient communication between clients and servers, gRPC provides a robust solution. Choose GraphQL when: Flexible data retrieval is required: If your application demands flexibility in data retrieval and allows clients to specify the exact data they need, GraphQL's query language provides a powerful and efficient solution. Reducing over-fetching and under-fetching is a priority: GraphQL helps eliminate over-fetching and under-fetching of data by allowing clients to request only the specific data they need. This is beneficial in scenarios where optimizing data transfer is crucial. Real-time updates are essential: If real-time features and the ability to subscribe to data updates are critical for your application (e.g., chat applications, live notifications), GraphQL's support for subscriptions makes it a strong contender. Ultimately, the choice between REST, gRPC, and GraphQL should be based on a careful evaluation of your project's requirements, existing infrastructure, and the specific features offered by each technology. Additionally, consider factors such as developer familiarity, community support, and ecosystem maturity when making your decision. It's also worth noting that hybrid approaches, where different technologies are used for different parts of an application, can be viable in certain scenarios. Conclusion The choice between REST, gRPC, and GraphQL is a nuanced decision that hinges on the specific requirements and objectives of a given project. REST, with its simplicity and widespread adoption, remains a solid choice for scenarios where ease of understanding and compatibility are paramount. Its statelessness and broad support make it an excellent fit for many web development projects. On the other hand, gRPC emerges as a powerful contender when high performance and efficiency are critical, particularly in microservices architectures. Its strong typing, bidirectional streaming, and automatic code generation make it well-suited for applications demanding low-latency communication and real-time updates. Meanwhile, GraphQL addresses the need for flexible data retrieval and the elimination of over-fetching and under-fetching, making it an optimal choice for scenarios where customization and optimization of data transfer are essential, especially in applications requiring real-time features. Ultimately, the decision should be guided by a careful assessment of project requirements, developer expertise, and the specific features offered by each technology, recognizing that a hybrid approach may offer a pragmatic solution in certain contexts.

Improving an organization's overall data capabilities enables teams to operate more efficiently. Emerging technologies have brought real-time data closer to business users, which plays a critical role in effective decision-making. In data analytics, the "hot path" and "cold path" refer to two distinct processing routes for handling data. The hot path involves real-time or near-real-time processing of data, where information is analyzed and acted upon immediately as it arrives. This path is crucial for time-sensitive applications, enabling quick responses to emerging trends or events. On the other hand, the cold path involves the batch processing of historical or less time-sensitive data, allowing for in-depth analysis, long-term trends identification, and comprehensive reporting, making it ideal for strategic planning and retrospective insights in data analytics workflows. In typical analytics solutions, the integration of incoming telemetry data with corresponding meta-data related to entities such as devices, users, or applications is a prerequisite on the server side before effective visualization in an application can occur. In this article, we will explore innovative methodologies for seamlessly combining data from diverse sources so that an effective dashboard can be built. The Event-Driven Architecture for Real-Time Anomalies Let's explore a real-time dashboard wherein administrators meticulously monitor network usage. In this scenario, live data on network usage from each device is transmitted in real-time, undergoing aggregation on the server side, inclusive of associating the data with respective client names before refreshing the user's table. In such use cases, the implementation of Event-Driven architecture patterns emerges as the optimal approach for ensuring seamless data processing and real-time insights. Event-driven design seamlessly orchestrates data flow between disparate microservices, enabling the aggregation of critical data points. Through clearly defined events, information from two distinct microservices is aggregated, ensuring real-time updates. The culmination of this event-driven approach provides a comprehensive and up-to-date representation of key metrics and insights for informed decision-making. In the depicted scenario, the telemetry data is seamlessly transmitted to the service bus for integration into the Dashboard service. Conversely, device metadata exhibits infrequent changes. Upon receipt of new telemetry events, the Dashboard service dynamically augments each record with all relevant metadata, presenting a comprehensive dataset for consumption by APIs. This entire process unfolds in real-time, empowering administrators to promptly identify network anomalies and initiate timely corrective measures. This methodology proves effective for those real-time scenarios, characterized by frequent incremental data ingestion to the server and a resilient system for processing those events. The Materialized View Architecture for Historical Reports For a historical report dashboard, adopting an event-driven approach might entail unnecessary effort, given that real-time updates are not imperative. A more efficient strategy would involve leveraging PostgreSQL Materialized Views, which is particularly suitable for handling bursty data updates. This approach allows for scheduled data crunching at predefined intervals, such as daily, weekly, or monthly, aligning with the periodic nature of the reporting requirements. PostgreSQL Materialized Views provide a robust mechanism for persistently storing the results of complex joins between disparate tables as physical tables. One of the standout advantages of materialized views is their ability to significantly improve the efficiency of data retrieval operations in APIs, as a considerable portion of the data is pre-computed. The incorporation of materialized views within PostgreSQL represents a substantial performance boost for read queries, particularly beneficial when the application can tolerate older, stale data. This feature serves to reduce disk access and streamline complex query computations by transforming the result set of a view into a tangible physical table. Let’s look at the above example with Device telemetry and metadata tables. The mat view can be created by the command below in SQL. SQL CREATE MATERIALIZED VIEW device_health_mat AS SELECT t.bsod_count, t.storage_used, t.date FROM device_telemetry t INNER JOIN device d ON t.ID = d.ID WITH DATA; Materialized views are beneficial in data warehousing and business intelligence applications where complex queries, data transformation, and aggregations are the norms. You can leverage materialized views when you have complex queries powering user-facing visualizations that need to load quickly to provide a great user experience. The only bottleneck with them is that the refresh needs to be explicitly done when the underlying tables have new data and can be scheduled with the command below. SQL REFRESH MATERIALIZED VIEW device_health_mat; (or) REFRESH MATERIALIZED VIEW CONCURRENTLY device_health_mat; In conclusion, while both aforementioned use cases share a dashboard requirement, the selection of tools and design must be meticulously tailored to the specific usage patterns to ensure the effectiveness of the solution.

Let’s say you’ve got 8 people on one of your engineering squads. Your daily standup takes 15 minutes a day. That’s 75 minutes per week, or roughly 3750 minutes per person. You’ve got 8 people, so that’s 30,000 minutes each year for your team or 500 hours. That works out to about 12.5 weeks spent in daily standup for your team.If your average engineer is earning $75,000, then you’re spending about $18,000 each year on your daily standup (not to mention opportunity cost, which is a whole topic in itself). But if your daily standups take 30 minutes, it costs you $36,000. And if you have 10 squads like this in your company, that’s $360,000. So we sure as heck better make our standups count! Five Ways I See Companies Waste Time in Standups (There Are More) The daily standup is envisioned as a 15-minute pulse check, but it often morphs into a parade of distractions, irrelevancies, and just plain inefficiencies. Company A The back-end engineering team at Company A religiously congregates every morning around their Scrum board. The standup never exceeds 15 minutes. But their updates are a monotonous loop of "I did X, today I'll do Y" – an agile charade with zero alignment with sprint goals. The engineers don’t even have sprint goals. The product manager prioritises the backlog, but no two-way conversations are happening. Problem 1: No Alignment With Sprint Goals Anecdotally, an engineer at a FinTech firm recently told me, “Strategic alignment comes from our initiative. I take the initiative to ask about it, but not everyone does that”. Lack of alignment with sprint goals leads to a lack of direction and purpose, causing team members to operate in isolation rather than as a cohesive unit working toward a shared objective. This inefficiency wastes valuable resources and could derail other tasks that are critical to the project. It also impacts stakeholder satisfaction and puts the team out of sync with broader strategic objectives. The very foundation of the Scrum framework is to inspect progress toward the Sprint Goal. Daily Scrums are designed for task updates and as opportunities to adapt and pivot towards achieving that Sprint Goal. Without this focal point, the team misses out on critical chances to adjust course, while eroding cohesion and motivation. Company B Company B has a fully distributed, remote team scattered across 9 hours’ worth of time zones. Ada, from Poland, finds that the live standup in her afternoon takes her out of her flow at peak concentration time. Brent in San Francisco grumbles about needing to log in early while juggling kids who haven't yet been sent off to school. And Clem, who, due to caregiving responsibilities, often misses the live standup, has to catch up through meeting reruns and often misses the chance to contribute. Problem 2: Operational Inefficiencies The logistical gymnastics needed for live standups often means getting in the way of engineers’ personal lives or interrupting their workflow. Time-zone clashes? Check. Flow state broken? Double-check. Is everyone mildly irritated? Triple-check. Problem 3: Lack of Flexibility More like a one-size-fits-none. Failing to adapt the standup format to cater to diverse needs and lifestyles often leads to dissatisfaction and poor adoption. And when you're remote, that dissatisfaction can quietly fester into full-blown detachment. Company C For Company C, the “daily standup” is something of a Proustian endeavour. Complex topics are discussed ad nauseam, sometimes taking up to 45-60 minutes a day. Today, Luis and Zaynab spend 15 minutes dissecting a problem, leaving everyone else twiddling their thumbs or heading off their second screen to multitask. 15 minutes turned out not to be long enough to fix it, and they decided to continue their chat later – but not until they’d wasted a collective 120 working minutes of engineering time for everyone else. A few of the team members are introverted, and the forum doesn’t feel like a good one for them to share their thoughts. They get meeting fatigue alongside the inevitable information overload. Problem 4: Redundancy and Overload When standups turn into mini-hackathons or ad hoc troubleshooting sessions, important issues either get glossed over or spiral into time-consuming digressions. We all end up stuck in this labyrinth of futile discussion, staggering out with meeting fatigue and information overload. Problem 5: Engagement At this point, people are emotionally checked out. The more vocal become inadvertent meeting hoggers, while others feel their contributions being sidelined. It's a fertile ground for a toxic culture that breeds disengagement and kills morale. How Asynchronous Standups (Sort Of) Help None of the scenarios we covered above captures the intended spirit of a stand-up meeting, which is to streamline the workflow and foster cohesion among team members. It's time to part ways with practices that suck the productivity out of our workday. So let’s consider asynchronous stand-ups. Traditional work schedules don't account for the natural ebb and flow of human energy, let alone the strain of managing personal lives alongside work commitments. Asynchronous stand-ups check a lot of boxes for the modern workforce. Where Asynchronous Stand-Ups Shine 1. Universal Participation: Time zones become irrelevant. Whether you're dialling in from Tokyo or Texas, you have an equal seat at the virtual table. 2. Your Pace, Your Place: These stand-ups play by your rules, allowing you to time your updates according to your work rhythm, not the other way around. 3. Efficiency: Bid farewell to meetings that drag on and interrupt your flow state. Asynchronous stand-ups are short and to the point. 4. Documented Progress: Think of it as an automatic diary of team updates. No need to chase minutes or compile reports; it's all there. 5. Quality Over Quantity: The chance to craft your update promotes clear and concise communication, rather than on-the-spot, often incoherent chatter. However, relying solely on asynchronous standups might not address all the complexities of collaboration effectively. In the current landscape, artificial intelligence stands prepared to integrate into your existing communication tools seamlessly. It can adeptly monitor and comprehend your projects and objectives, capturing the essence of decisions and activities that mould them. Unlike humans, who grapple with the inability to retain every detail and extract the pertinent elements, AI remains unhindered by these constraints. Our memory is finite, we lose sight of our goals, and overlook occurrences, all due to the limitations of time. AI, on the other hand, operates outside of these confines, positioning it as a far superior contender to succinctly summarise daily events or provide insights into ongoing matters. Getting Asynchronous Stand-Ups Right Asynchronous stand-ups work when everyone’s on the same page about how to do them at your organisation. Always ensure everyone understands what’s expected of them, and how to go about their asynchronous stand-up. Stay Consistent: Insist on a clear format that focuses on completed tasks, work in progress, and any roadblocks. Flag for Follow-up: Asynchronous doesn't mean antisocial. Urgent matters should be highlighted for immediate attention. A virtual pow-wow can still happen if needed. Time Frames Matter: Establish a window within which all updates and responses should be posted to maintain momentum. Clear Paths for Emergencies: Identify a procedure for raising and addressing urgent issues promptly. Making AI Alternatives Work Human memory has its limitations. We're bound to forget, overlook, or downright miss out on crucial updates. AI doesn't share these shortcomings. To make the most out of this tool, just stick to some collaboration fundamentals: Open Dialogue: Transparency is key. Holding the majority of discussions in private channels or direct messages is generally not advisable unless there's a specific reason like confidentiality concerns or data protection. Use Your Tools Effectively: Whether it's crafting well-structured Git commits, keeping your Jira boards current, or meticulously documenting workflows in Notion, encourage correct tool usage across the board. The beauty of AI is its ability to draw smart conclusions from the data it's given. By actively participating in an AI-enhanced asynchronous stand-up, your team stands to gain significantly. AI tools can highlight important activities and provide clear answers to any queries about ongoing projects.

Snowflake's evolution over the last few years is simply amazing. It is currently a data platform with a great ecosystem both in terms of partners and a wide variety of components like snowgrid, snowpark, or streamlit, but in this article, we are not going to focus on its role as a modern cloud-based data warehouse. It revolutionizes the traditional concept of data warehousing; it offers a more agile and scalable platform that separates storage, computing, and services, allowing each component to scale independently. This means you can store unlimited data, ramp up or down your computing resources based on your querying needs, and only pay for what you use. Currently, we can say that Snowflake is mainly an Online Analytical Processing (OLAP) type solution, but as we see further on, it is evolving to provide transactional and analytical capabilities in a single platform. Below is a high-level architecture diagram showing the layers that are part of Snowflake. Cloud Services Layer: It coordinates and handles tasks that are not specific to querying or storing data. It includes several tasks, such as authenticating user sessions, role-based access control, or ensuring transactional consistency. Compute Layer: This layer is where the actual data processing happens. It comprises one or multiple virtual warehouses, which are essentially clusters of compute resources. Each virtual warehouse can scale up or down independently and can be started or stopped to optimize costs. Storage Layer: This layer is responsible for the storage of structured and semi-structured data. It is stored in cloud storage in a columnar format. Optimized for Analytical Queries Snowflake is designed for big data analytics. It can handle complex queries on large datasets efficiently due to its columnar storage and massively parallel processing (MPP) architecture. Analytical queries typically work with a subset of columns and operations to aggregate, transform, and analyze vast volumes of data to provide insights, trends, or patterns. These are some of the common operations used in analytical queries: Aggregations: Functions like SUM(), AVG(), COUNT(), and MAX() are usually used to summarize data. Range scans: Scan wide ranges of data (e.g. WHERE sale_date BETWEEN '2022-01-01' AND '2022-12-31') Group by: Grouping data using GROUP BY clauses in combination with aggregation functions to provide summaries by some attribute. Ordering and windows function: Use ordering (ORDER BY) and window functions (e.g., ROW_NUMBER(), LAG(), LEAD()) to calculate running totals, ranks, and other advanced analytics. Let's see it in an example to help us understand it: Columnar Storage, the Foundation of Performance Columnar storage, as opposed to row-based storage, manages data using columns (product_id, name, sale_date, etc.) as logical units that are used to store the information in memory. Each logical unit always stores the same data type, which means that the adjacent data in memory all have the same type of data. This strategy provides a number of performance benefits: Data access efficiency: Aggregation queries, like those calculating sums or averages, often require data from only a few columns rather than the entire row. In columnar storage, data is stored column by column. This means that when executing an aggregation on a specific column, the database system can read only the data for that column, skipping over all other unrelated columns. This selective reading can significantly reduce I/O operations and speed up query performance. Compression: Data within a column tends to be more homogeneous (i.e., of the same type and often with similar values) compared to data within a row. This homogeneity makes column data more amenable to compression techniques. For example, if a column storing a month of transaction dates mostly has the same few dates, you can represent those repeated dates once with a count instead of storing them repeatedly. Effective compression reduces storage costs and can also boost performance by reducing the amount of data read from storage. Better CPU cache utilization: Since columnar databases read contiguous memory blocks from a single column, they can better utilize CPU caches. The data loaded into the cache is more likely to be used in the subsequent operations, leading to fewer cache misses. On the other hand, in row-based systems, if only a few columns from a wide row are needed, much of the cached data might go unused. Eliminating irrelevant data quickly: Many columnar databases use metadata about blocks of columnar data, like min and max values. This metadata can quickly determine if a block contains relevant data or can be skipped entirely. For instance, if a query is filtering for pricing over 200, and the maximum value in a block is 110, the entire block can be ignored. In the following diagram, we explain in a simple way how columnar storage could work to help you understand why it is efficient in analytical queries. But it does not mean that Snowflake implements this logic. In this example, the values of each column can be stored in the same order: the first value of the product_id corresponds to the first value in the sales_Data and to the first in the amount; the second to the second to the second, and so on. Therefore when you filter by date, you can quickly get the offsets assigned for the start and end of the timestamp range and also give the offset of the corresponding values in the amount and perform the necessary calculations. Unistore Unifying Analytical and Transactional Data Snowflake is evolving its platform by applying a modern approach to provide transactional and analytical data operations together in a single platform. The new feature is called Unistore and enables running transactional by offering fast single-row operations. Therefore, Snowflake joins a small group of cloud-based databases that offer this type of capability, such as SingleStore or MySQL Heatwave. This feature is still in private preview and has limited access, so we will have to verify the latency times. It should be considered that there are other features of transactional and relational databases, such as referential integrity that are not supported. Row Storage, Transactional Performance Typically, databases are oriented to work at the row level, and queries or operations use row-based storage or row-oriented storage. It is a method in which data is stored by rows. It is especially effective for transactional online transaction processing (OLTP) and workloads that frequently involve single-row queries or operations. Some of the benefits of using this type of storage are listed below: Fewer columns in OLTP queries: Transactional queries, like those from web applications or operational systems, often involve a limited number of columns but require complete rows. In such scenarios, reading a full row from row-based storage is more efficient than assembling a row from multiple columns in columnar storage. Optimized for transactional workloads: OLTP systems often have a high number of small, frequent read and write operations. When updating or inserting a new row in row-based storage, the database writes the whole row at once. This contrasts with columnar systems where an insert or update might involve writing data across various column files. Locking and concurrency: Row-based databases are often optimized for row-level locking. This means that when a row is being updated, the database can lock just that specific row, allowing other operations to proceed concurrently on other rows. This level of granularity in locking is beneficial for high-concurrency transactional systems. Snowflake Platform Layers Cloud Services The Cloud Services layer plays a crucial role in managing and optimizing the overall functionality of the data warehouse and acts as the "brain" that orchestrates processes and resources to deliver a seamless, secure, and scalable data analysis and management experience. It's responsible for handling a wide range of tasks, from authentication and infrastructure management to metadata maintenance and query optimization. It is probably the most unknown layer, which means it is a user-friendly layer that goes unnoticed precisely because of its efficiency and simplicity. This layer offers several key features: Query processing: It receives SQL queries, parses them, and optimizes them for efficient execution, distributing the workload across its compute resources. Metadata management: It maintains metadata for the data stored that includes information about table structures, data types, and compression methods, as well as query history and performance metrics. Access control and security management: It handles user authentication, authorization, and role-based access control. It ensures that users can only access the data and perform the actions their roles permit. Transaction management: Handle the main features of transaction processing, including concurrency control and ensuring the ACID (Atomicity, Consistency, Isolation, Durability) properties of transactions. That, in conjunction with storage layer features (durability, consistency, or data versioning), is crucial for maintaining data integrity and consistency. Infrastructure management: It dynamically allocates and scales computational resources, the Virtual Warehouses, automatically scaling them up or down based on the workload. Data sharing and collaboration: It facilitates secure data sharing across different Snowflake accounts, sharing subsets of data without copying or moving the data, enabling real-time and seamless collaboration. Performance and usage monitoring: It provides tools and dashboards for monitoring the performance and usage of the Snowflake environment. Although, in my opinion, this is one of Snowflake's capabilities that can be improved. Integrations and API support: It provides support for various integrations and APIs, allowing users, applications, and tools to interact with the Snowflake platform. For example, it allows the management of all resources (compute, user management, monitoring, or security) following an as-code approach. Compute Layer This layer is composed of virtual warehouses that are essentially compute clusters and are responsible for executing SQL queries on the data stored in Snowflake. It supports creating multiple virtual warehouses to handle and distribute your workloads. This enables us to create dedicated and sized resources for each scenario or actor. For example, if you have different squads accessing data concurrently on top of the applications and BI tools, we can create and assign their own warehouse, ensuring that heavy querying by some of them doesn't affect another's performance. Isolation: Each cluster is a component isolated from the rest and, therefore, is not affected by the load state of other clusters. Independent scaling: It supports scale-up and scale-out independently for each cluster. If you need more performance for larger queries or more users, you can increase the size of your warehouse or add more nodes using multi-clustering capabilities. Independent elasticity: It supports automatic scale-out, although vertical scaling is not automated and, therefore requires us to perform manual or automatic actions. On-the-fly resizing: Scaling a virtual warehouse in Snowflake can be done on the fly without any downtime. This allows for elasticity, where you can adapt to varying workloads as needed. Multi-cluster warehouses: For even higher levels of concurrency, it enables scale-out automatically from one cluster to multiple compute clusters to accommodate many simultaneous users or queries. Storage Layer It is responsible for storing and managing data efficiently and contributes to having an effective and scalable platform. It offers several key features: Types of data: Snowflake supports structured and semi-structured data, including JSON, Avro, XML, Parquet formats, or Iceberg tables. Elastic and Scalable Storage: The storage layer automatically scales to accommodate data growth without manual intervention, so we do not need to worry about storage limits or provisioning additional storage space. Optimized data storage format: it stores data in an optimized columnar format or in row format in the case of Unistore tables, which can be indexed like traditional OLTP engines. Optimizing storage for each data use case. Data clustering and micro-partitions: Snowflake automatically organizes data into micro-partitions, which are internally optimized and compressed to improve query performance in terms of time and compute resources. Time travel and fail-safe features: It provides the capacity to access historical data up to a certain point in the past at table level. This allows us to revert to previous data states within a specified time window, providing data protection and ensuring data integrity or performing historical data analysis. The fail-safe feature offers additional protection by maintaining the data for a set period for disaster recovery. Data sharing: Snowflake enables secure and easy sharing of data between different Snowflake accounts. This feature allows organizations to share live, ready-to-query data with partners and customers without moving or copying data, ensuring data governance and security. Security and compliance: It provides several security features, including encryption of data at rest and in transit, role-based access control, and compliance with various industry standards and regulations. Cost-effective storage: We pay only for the storage they use, with Snowflake compressing and storing data in a cost-efficient manner. Conclusions In this series of articles, we will explore the various ways in which Snowflake can be used to address a wide range of data challenges. We will start with the basics of SQL and how to use it to query data in Snowflake. We will then move on to more advanced topics such as data modeling, query optimization, and machine learning. Before embarking on any project, it is crucial to understand its underlying architecture, capabilities, and limitations. Failure to understand the nuances of products and platforms can lead to inefficiencies, performance bottlenecks, excessive costs, and potential security vulnerabilities. This is precisely the purpose of this first article, to understand Snowflake's architecture and fundamental features.

By Miguel Garcia CORE

In an ideal world, there are no zero-day security patches that absolutely must be applied today. There are no system outages - shortage never becomes full; APIs don't stop accepting parameters they accepted yesterday, users don't call support desks with tricky problems and everyone else writes code as good as you do so there are no bugs. Maybe one day, but until then, there is unplanned but urgent work. Whether you call it DevOps, support, maintenance, or some other euphemism, it is work that just appears and demands to be done. The problem is this work is highly disruptive and destroys the best-laid plans. While sticking one's head in the sand and pretending the work does not exist, it does exist and it demands attention. The question then is: how best can such work be managed? Step 1: Acceptance Despite attempts by Project Managers and Scrum Masters to keep teams dedicated to shiny new things, "Stuff happens," as they say. So to start off with, everyone needs to stop wishful thinking. Put it this way: if you come up with a way of handling unplanned but urgent work and it never happens again then you have only lost a few hours of thinking. However, if you don't plan and it does happen then it is going to take up a lot more time and effort. Let's also accept that there is no Bug Fixing Fairy or DevOps Goblin. One day ChatGPT might be able to handle the unexpected, but until then, doing this work is going to require time and effort from the people who would otherwise be doing the shiny new stuff. There is only one pot of capacity and if Lenny is applying a security patch, she isn't working on new features. Step 2: Capture and Make Visible Back in the days of physical boards, I would write out a yellow card and put it on the board. These days it is probably a ticket in an electronic system; however, you do it to make sure those tickets are easily identified so people can easily see them and they can be found later. This may sound obvious, but an awful lot of unplanned work is done under the covers; because "it should not exist," some people object to it being done. Even when the work is trivial it still represents disruption and task switching, and it might fall disproportionally on some individuals. A few years ago I met a team who were constantly interrupted by support work. They felt they couldn't do anything new because of the stream of small, and large, unexpected work. I introduced the yellow card system and with that one change, the problem went away. What happened was that it quickly became clear that the team had, on average, only one unexpected urgent request a week. But because the requests were high profile, people kept asking about them and pressure was heaped on to fix it. Once the request was a clearly identifiable yellow card on a work board, everybody in the company could see it. Anyone could walk up to the board and see the status and who was working on it. Overnight the bulk of the interruptions went away. A lot of the previous interruptions had been people asking, "What is happening?" It was that simple. Once the work is captured and made visible, people can start to see that requests are respected and action taken. Now attention can turn to priority. Step 3: Meaningful Prioritization When trust is absent, nobody believes that anything will be done so everyone demands their ask has top priority. In time, as people learn requests are respected and acted on; then meaningful priority decisions can be made. I met a company where one of the founders had a habit of picking up customer requests, walking across to a dev team member, and asking, "Can you just...?" Of course, the dev wouldn't say "no" to a founder, so their work was interrupted. In addition to the yellow card, a priority discussion was needed. The team was practicing a basic Agile system with all the work for the next Sprint listed in priority order on their Kanban board. When the founder came over, the dev would write the request on a yellow card, then walk over to the Kanban board and ask, "You can see the card I'm working on right now: should I stop what I'm doing and do the new request?" If the founder said "yes," then the dev would honor the request. But seeing what would be interrupted, the founder was likely to say, "Well, finish that first." Now the dev would put the card next to the priority work queue and ask, "Is this the new priority number one?" If it was, the card went to the top of the queue and the next available person would pick it up. If not, the dev would work down the list: "The new priority two? three? four?" We had a simple feedback process. Beforehand, the founder had no idea of the consequences of asking, "Can you just. . .?" Now they could see what work would be delayed, displaced, and interrupted. These three steps alone can manage a lot of unplanned but urgent work and improve team performance quickly, yet it can still be better provided your ticketing system is capturing all these instances physically or electronically. Step 4: Use Data To Get Better At the most basic level, count the yellow cards and count the other planned work cards. Now calculate the ratio of how much planned v. unplanned work is going on over time and feed this back into planning. For example, one development manager calculated that unplanned work accounted for 20% to 25% of the team's Sprint on average (using several months of data.) So to start with, they scheduled 20% less work per Sprint. This alone made the team more predictable. You don't even need to bother with estimates here - you can if you really want to, but this is not going to be perfect, just good enough. Simply knowing the ratio is a start. Over time you may refine your calculations, but start simple. Step 5: Fix at Source Use the yellow tickets as part of your retrospective. Start by considering if the tickets really did deserve to be fast-tracked into work. The team should talk about this with the Product Owner/Manager and other stakeholders. Now everyone can appreciate the impact you might find that some requests really shouldn't be prioritised. Next, you can look at the nature of the requests and see if there is some pattern. Perhaps many originate from one stakeholder. Perhaps somebody should go and talk with them about why they generate so many unplanned requests - maybe they can start making requests before Sprint planning. Similarly, it might be one customer who is raising many tickets. Perhaps this customer has some specific problems, perhaps they have never had training or simply don't appreciate how the system works. It could be that some particular sub-system or third-party component is causing problems. Some remedial work/some refactoring could help, or maybe the component needs to be replaced entirely. When there is data arguing for the time to do such work is a lot easier. You might find that the team lacks particular skills or needs expansion. The same manager who budgeted for 20% of unplanned work later analyzed the tickets and found that the majority of the unplanned tickets were for general IT support which didn't need specialist coding skills. These findings were taken to the big boss and permission was quickly given to hire an IT support technician. Getting a 20% boost to programmer productivity for less than the cost of another coder was too good a deal to miss! Sometimes expanding the team isn't an option, and sometimes the tickets don't point to a missing skill. Another solution is the "sacrificial one." In these cases, a team of five experiencing 20% unplanned work will have one member handle the unplanned stuff. This means one team member soaks up all the interruptions which allows the others to stay focused. Few people like being the sacrificial lamb so rotate the position regularly; say, every Sprint. In one example, team members were concerned it would not work because they each specialized in different parts of the system. They agreed to try and work on any ticket that came up during their week as on-support. Even though it would take them longer than a colleague who specialized in that part of the system, it could increase overall throughput. After a few weeks, team members found they could deal with far more tickets than they expected and were learning more about the system. If they were stuck they might get just 10 minutes of the specialist and then do it themselves. Work the Problem The thing is as much as you don't want unplanned and urgent work to exist, it does. Project Managers have spent years trying to stamp it out and, without great pain, they can't. In fact, the whole DevOps movement runs counter to this school of thought. The five steps set out here might not create the ideal world but they should make the real world more controlled and manageable. One day AI systems might take over unplanned work, but it is often in unexpected situations when things should work but don't that human ingenuity is needed most.

By Allan Kelly CORE

These days, writing tests is a standard part of development. Unfortunately, we need to deal from time to time with a situation when a static method is invoked by a tested component. Our goal is to mitigate this part and avoid third-party component behavior. This article sheds light on the mocking of static methods by using the "inline mock maker" introduced by Mockito in the 3.4 version. In other words, this article explains Mockito.mockStatic method in order to help us with unwanted invocation of the static method. In This Article, You Will Learn How to mock and verify static methods with mockStatic feature How to setup mockStatic in different Mockito versions Introduction Many times, we have to deal with a situation when our code invokes a static method. It can be our own code (e.g., some utility class or class from a third-party library). The main concern in unit testing is to focus on the tested component and ignore the behavior of any other component (including static methods). An example is when a tested method in component A is calling an unrelated static method from component B. Even so, it's not recommended to use static methods; we see them a lot (e.g., utility classes). The reasoning for avoiding the usage of static methods is summarized very well in Mocking Static Methods With Mockito. Generally speaking, some might say that when writing clean object-orientated code, we shouldn’t need to mock static classes. This could typically hint at a design issue or code smell in our application. Why? First, a class depending on a static method has tight coupling, and second, it nearly always leads to code that is difficult to test. Ideally, a class should not be responsible for obtaining its dependencies, and if possible, they should be externally injected. So, it’s always worth investigating if we can refactor our code to make it more testable. Of course, this is not always possible, and sometimes we need to mock static methods. A Simple Utility Class Let's define a simple SequenceGenerator utility class used in this article as a target for our tests. This class has two "dumb" static methods (there's nothing fancy about them). The first nextId method (lines 10-12) generates a new ID with each invocation, and the second nextMultipleIds method (lines 14-20) generates multiple IDs as requested by the passed argument. Java @UtilityClass public class SequenceGenerator { private static AtomicInteger counter; static { counter = new AtomicInteger(1); } public static int nextId() { return counter.getAndIncrement(); } public static List<Integer> nextMultipleIds(int count) { var newValues = new ArrayList<Integer>(count); for (int i = 0; i < count; i++) { newValues.add(counter.getAndIncrement()); } return newValues; } } MockedStatic Object In order to be able to mock static methods, we need to wrap the impacted class by "inline mock maker." The mocking of static methods from our SequenceGenerator class introduced above is achievable by MockedStatic instance retrieved via Mockito.mockStatic method. This can be done as: Java try (MockedStatic<SequenceGenerator> seqGeneratorMock = mockStatic(SequenceGenerator.class)) { ... } Or Java MockedStatic<SequenceGenerator> seqGeneratorMock = mockStatic(SequenceGenerator.class)); ... seqGeneratorMock.close(); The created mockStatic instance has to be always closed. Otherwise, we risk ugly side effects in next tests running in the same thread when the same static method is involved (i.e., SequenceGenerator in our case). Therefore, the first option seems better, and it is used in most articles on this topic. The explanation can be found on the JavaDoc site (chapter 48) as: When using the inline mock maker, it is possible to mock static method invocations within the current thread and a user-defined scope. This way, Mockito assures that concurrently and sequentially running tests do not interfere. To make sure a static mock remains temporary, it is recommended to define the scope within a try-with-resources construct. To learn more about this topic, check out these useful links: The official site, JavaDoc site and GitHub repository. Mock Method Invocation Static methods (e.g., our nextId or nextMultipleIds methods defined above) can be mocked with MockedStatic.when. This method accepts a functional interface defined by MockedStatic.Verification. There are two cases we can deal with. Mocked Method With No Argument The simplest case is mocking a static method with no argument (nextId method in our case). In this case, it's sufficient to pass to seqGeneratorMock.when method only a method reference (see line 5). The returned value is specified in a standard way (e.g., with thenReturn method). Java @Test void whenWithoutArgument() { try (MockedStatic<SequenceGenerator> seqGeneratorMock = mockStatic(SequenceGenerator.class)) { int newValue = 5; seqGeneratorMock.when(SequenceGenerator::nextId).thenReturn(newValue); assertThat(SequenceGenerator.nextId()).isEqualTo(newValue); } } Mocked Method With One or More Arguments Usually, we have a static method with some arguments (nextMultipleIds in our case). Then, we need to use a lambda expression instead of the method reference (see line 5). Again, we can use the standard methods (e.g. then, thenRetun, thenThrow etc.) to handle the response with the desired behavior. Java @Test void whenWithArgument() { try (MockedStatic<SequenceGenerator> seqGeneratorMock = mockStatic(SequenceGenerator.class)) { int newValuesCount = 5; seqGeneratorMock.when(() -> SequenceGenerator.nextMultipleIds(newValuesCount)) .thenReturn(List.of(1, 2, 3, 4, 5)); assertThat(SequenceGenerator.nextMultipleIds(newValuesCount)).hasSize(newValuesCount); } } Verify Method Invocation Similarly, we can also verify calls of the mocked component by calling seqGeneratorMock.verify method for the method reference (see line 7) Java @Test void verifyUsageWithoutArgument() { try (MockedStatic<SequenceGenerator> seqGeneratorMock = mockStatic(SequenceGenerator.class)) { var person = new Person("Pamela"); seqGeneratorMock.verify(SequenceGenerator::nextId); assertThat(person.getId()).isEqualTo(0); } } Or the lambda expression (see line 6). Java @Test void verifyUsageWithArgument() { try (MockedStatic<SequenceGenerator> seqGeneratorMock = mockStatic(SequenceGenerator.class)) { List<Integer> nextIds = SequenceGenerator.nextMultipleIds(3); seqGeneratorMock.verify(() -> SequenceGenerator.nextMultipleIds(ArgumentMatchers.anyInt())); assertThat(nextIds).isEmpty(); } } Note: please be aware that seqGeneratorMock doesn't provide any value here, as the static methods are still mocked with the defaults. There's no spy version so far. Therefore, any expected return value has to be mocked, or the default value is returned. Setup The mockStatic feature is enabled in Mockito 5.x by default. Therefore, no special setup is needed. But we need to set up Mockito for the older versions (e.g., 4.x). Mockito 5.x+ As it was already mentioned, we don't need to set up anything in version 5.x. See the statement in the GitHub repository: Mockito 5 switches the default mockmaker to mockito-inline, and now requires Java 11. Old Mockito Versions When an older version is used, and we use the mock-inline feature via mockStatic then we can see an error like this: Plain Text org.mockito.exceptions.base.MockitoException: The used MockMaker SubclassByteBuddyMockMaker does not support the creation of static mocks Mockito's inline mock maker supports static mocks based on the Instrumentation API. You can simply enable this mock mode, by placing the 'mockito-inline' artifact where you are currently using 'mockito-core'. Note that Mockito's inline mock maker is not supported on Android. at com.github.aha.poc.junit.person.StaticUsageTests.mockStaticNoArgValue(StaticUsageTests.java:15) at java.base/java.lang.reflect.Method.invoke(Method.java:580) at java.base/java.util.ArrayList.forEach(ArrayList.java:1596) at java.base/java.util.ArrayList.forEach(ArrayList.java:1596) Generally, there are two options to enable it for such Mockito versions (see all Mockito versions here). Use MockMaker Resource The first option is based on adding <project>\src\test\resources\mockito-extensions\org.mockito.plugins.MockMaker to our Maven project with this content: Plain Text mock-maker-inline Use mock-inline Dependency The other, and probably better, option is adding mockito-inline dependency: XML <dependency> <groupId>org.mockito</groupId> <artifactId>mockito-inline</artifactId> <version>5.2.0</version> <scope>test</scope> </dependency> Note: this dependency already contains MockMaker resource mentioned above. Therefore, this option seems more convenient. Maven Warning No matter what version is used (see above), Maven build can produce these warnings: Plain Text WARNING: A Java agent has been loaded dynamically (<user_profile>\.m2\repository\net\bytebuddy\byte-buddy-agent\1.12.9\byte-buddy-agent-1.12.9.jar) WARNING: If a serviceability tool is in use, please run with -XX:+EnableDynamicAgentLoading to hide this warning WARNING: If a serviceability tool is not in use, please run with -Djdk.instrument.traceUsage for more information WARNING: Dynamic loading of agents will be disallowed by default in a future release OpenJDK 64-Bit Server VM warning: Sharing is only supported for boot loader classes because bootstrap classpath has been appended Mockito works correctly even with these warnings. It's probably caused by/depends on the used tool, JDK version, etc. Conclusion In this article, the mocking of static methods with the help of Mockito inline mock maker was covered. The article started with the basics of static mocking and then followed with a demonstration of when and verify usage (either with the method reference or the lambda expression). In the end, the setup of the Mockito inline maker was shown for different Mockito versions. The used source code can be found here.

By Arnošt Havelka CORE

This is an article from DZone's 2023 Observability and Application Performance Trend Report.For more: Read the Report From cultural and structural challenges within an organization to balancing daily work and dividing it between teams and individuals, scaling teams of site reliability engineers (SREs) comes with many challenges. However, fostering a resilient site reliability engineering (SRE) culture can facilitate the gradual and sustainable growth of an SRE team. In this article, we explore the challenges of scaling and review a successful scaling framework. This framework is suitable for guiding emerging teams and startups as they cultivate an evolving SRE culture, as well as for established companies with firmly entrenched SRE cultures. The Challenges of Scaling SRE Teams As teams scale, complexity may increase as it can be more difficult to communicate, coordinate, and maintain a team's coherence. Below is a list of challenges to consider as your team and/or organization grows: Rapid growth – Rapid growth leads to more complex systems, which can outpace the capacity of your SRE team, leading to bottlenecks and reduced reliability. Knowledge-sharing – Maintaining a shared understanding of systems and processes may become difficult, making it challenging to onboard new team members effectively. Tooling and automation – Scaling without appropriate tooling and automation can lead to increased manual toil, reducing the efficiency of the SRE team. Incident response – Coordinating incident responses can become more challenging, and miscommunications or delays can occur. Maintaining a culture of innovation and learning – This can be challenging as SREs may become more focused on solving critical daily problems and less focused on new initiatives. Balancing operational and engineering work – Since SREs are responsible for both operational tasks and engineering work, it is important to ensure that these teams have enough time to focus on both areas. A Framework for Scaling SRE Teams Scaling may come naturally if you do the right things in the right order. First, you must identify what your current state is in terms of infrastructure. How well do you understand the systems? Determine existing SRE processes that need improvement. For the SRE processes that are necessary but are not employed yet, find the tools and the metrics necessary to start. Collaborate with the appropriate stakeholders, use feedback, iterate, and improve. Step 1: Assess Your Current State Understand your system and create a detailed map of your infrastructure, services, and dependencies. Identify all the components in your infrastructure, including servers, databases, load balancers, networking equipment, and any cloud services you utilize. It is important to understand how these components are interconnected and dependent on each other — this includes understanding which services rely on others and the flow of data between them. It's also vital to identify and evaluate existing SRE practices and assess their effectiveness: Analyze historical incident data to identify recurring issues and their resolutions. Gather feedback from your SRE team and other relevant stakeholders. Ask them about pain points, challenges, and areas where improvements are needed. Assess the performance metrics related to system reliability and availability. Identify any trends or patterns that indicate areas requiring attention. Evaluate how incidents are currently being handled. Are they being resolved efficiently? Are post-incident reviews being conducted effectively to prevent recurrences? Step 2: Define SLOs and Error Budgets Collaborate with stakeholders to establish clear and meaningful service-level objectives (SLOs) by determining the acceptable error rate and creating error budgets based on the SLOs. SLOs and error budgets can guide resource allocation optimization. Computing resources can be allocated to areas that directly impact the achievement of the SLOs. SLOs set clear, achievable goals for the team and provide a measurable way to assess the reliability of a service. By defining specific targets for uptime, latency, or error rates, SRE teams can objectively evaluate whether the system is meeting the desired standards of performance. Using specific targets, a team can prioritize their efforts and focus on areas that need improvement, thus fostering a culture of accountability and continuous improvement. Error budgets provide a mechanism for managing risk and making trade-offs between reliability and innovation. They allow SRE teams to determine an acceptable threshold for service disruptions or errors, enabling them to balance the need for deploying new features or making changes to maintain a reliable service. Step 3: Build and Train Your SRE Team Identify talent according to the needs of each and every step of this framework. Look for the right skillset and cultural fit, and be sure to provide comprehensive onboarding and training programs for new SREs. Beware of the golden rule that culture eats strategy for breakfast: Having the right strategy and processes is important, but without the right culture, no strategy or process will succeed in the long run. Step 4: Establish SRE Processes, Automate, Iterate, and Improve Implement incident management procedures, including incident command and post-incident reviews. Define a process for safe and efficient changes to the system. Figure 1: Basic SRE process One of the cornerstones of SRE involves how to identify and handle incidents through monitoring, alerting, remediation, and incident management. Swift incident identification and management are vital in minimizing downtime, which can prevent minor issues from escalating into major problems. By analyzing incidents and their root causes, SREs can identify patterns and make necessary improvements to prevent similar issues from occurring in the future. This continuous improvement process is crucial for enhancing the overall reliability and performance whilst ensuring the efficiency of systems at scale. Improving and scaling your team can go hand in hand. Monitoring Monitoring is the first step in ensuring the reliability and performance of a system. It involves the continuous collection of data about the system's behavior, performance, and health. This can be broken down into: Data collection – Monitoring systems collect various types of data, including metrics, logs, and traces, as shown in Figure 2. Real-time observability – Monitoring provides real-time visibility into the system's status, enabling teams to identify potential issues as they occur. Proactive vs. reactive – Effective monitoring allows for proactive problem detection and resolution, reducing the need for reactive firefighting. Figure 2: Monitoring and observability Alerting This is the process of notifying relevant parties when predefined conditions or thresholds are met. It's a critical prerequisite for incident management. This can be broken down into: Thresholds and conditions – Alerts are triggered based on predefined thresholds or conditions. For example, an alert might be set to trigger when CPU usage exceeds 90% for five consecutive minutes. Notification channels – Alerts can be sent via various notification channels, including email, SMS, or pager, or even integrated into incident management tools. Severity levels – Alerts should be categorized by severity levels (e.g., critical, warning, informational) to indicate the urgency and impact of the issue. Remediation This involves taking actions to address issues detected through monitoring and alerting. The goal is to mitigate or resolve problems quickly to minimize the impact on users. Automated actions – SRE teams often implement automated remediation actions for known issues. For example, an automated scaling system might add more resources to a server when CPU usage is high. Playbooks – SREs follow predefined playbooks that outline steps to troubleshoot and resolve common issues. Playbooks ensure consistency and efficiency during remediation efforts. Manual interventions – In some cases, manual intervention by SREs or other team members may be necessary for complex or unexpected issues. Incident Management Effective communication, knowledge-sharing, and training are crucial during an incident, and most incidents can be reproduced in staging environments for training purposes. Regular updates are provided to stakeholders, including users, management, and other relevant teams. Incident management includes a culture of learning and continuous improvement: The goal is not only to resolve the incident but also to prevent it from happening again. Figure 3: Handling incidents A robust incident management process ensures that service disruptions are addressed promptly, thus enhancing user trust and satisfaction. In addition, by effectively managing incidents, SREs help preserve the continuity of business operations and minimize potential revenue losses. Incident management plays a vital role in the scaling process since it establishes best practices and promotes collaboration, as shown in Figure 3. As the system scales, the frequency and complexity of incidents are likely to increase. A well-defined incident management process enables the SRE team to manage the growing workload efficiently. Conclusion SRE is an integral part of the SDLC. At the end of the day, your SRE processes should be integrated into the entire process of development, testing, and deployment, as shown in Figure 4. Figure 4: Holistic view of development, testing, and the SRE process Iterating on and improving the steps above will inevitably lead to more work for SRE teams; however, this work can pave the way for sustainable and successful scaling of SRE teams at the right pace. By following this framework and overcoming the challenges, you can effectively scale your SRE team while maintaining system reliability and fostering a culture of collaboration and innovation. Remember that SRE is an ongoing journey, and it is essential to stay committed to the principles and practices that drive reliability and performance. This is an article from DZone's 2023 Observability and Application Performance Trend Report.For more: Read the Report