Pipi autonomous Read-Eval-Print-Loop (REPL)

Mike's Notes

Deployment roadmap

Later in the year, Pipi will be able to deploy infrastructure on any platform using Infrastructure as Code (IaC).

Options on how to do this include;

  • CL (Command Line)
  • REPL (Read-Eval-Print-Loop)
  • API

Implementing a REPL (Read-Eval-Print-Loop) programmatically in CFML

I asked Google Search AI Mode (powered by Google Gemini) how to use CFML to write and read REPL.

The Google output has been reformatted but not edited, and the code needs to be tested. The questions were turned into headings. There is a lot of duplication.

I find that carefully using Gemini to write CFML code and then checking everything is making me more productive.

There is now enough here to set up REPL.

Once this automation is complete, productivity will increase by at least x10.

Resources

References

  • Reference

Repository

  • Home > Ajabbi Research > Library >
  • Home > Handbook > 

Last Updated

04/04/2026

Pipi autonomous Read-Eval-Print-Loop (REPL)

By: Mike Peters and Gemini
On a Sandy Beach: 04/04/2026

Mike is the inventor and architect of Pipi and the founder of Ajabbi.

Gemini is still cool.

A Read-Eval-Print-Loop (REPL) is an interactive computer programming environment that accepts single-user input, executes it, and returns the result immediately. It is also known as an interactive toplevel or language shell. [1, 2, 3] 

The Four Steps of the Loop

The name describes the precise cycle the environment follows: [4, 5] 

  • Read: The system accepts a line of input (usually a single expression or command) from the user.
  • Eval: It parses and evaluates the input code to determine its value or effect.
  • Print: The resulting value or output is displayed back to the user on the screen.
  • Loop: The process repeats, returning to the prompt to wait for the next input. [1, 5, 6, 7, 8, 9, 10] 

Why Developers Use REPLs

REPLs are highly valued for their tight feedback loop, which allows for: [6, 7, 11] 

  • Interactive Prototyping: Quickly testing small snippets of code without creating and saving files.
  • Debugging: Investigating the state of a program and testing potential fixes in real-time.
  • Learning: Experimenting with new language features or libraries with instant results.
  • Calculations: Using the environment as a high-powered calculator for mathematical expressions. [1, 12, 13, 14, 15, 16, 17] 

Common Examples

Most modern programming languages provide a built-in REPL or have popular third-party versions: [1, 18] 

References

Implementing REPL programmatically in CFML

Implementing a REPL (Read-Eval-Print-Loop) programmatically in CFML involves creating a loop that captures user input, evaluates it as live code, and returns the result. [1, 2, 3] 

While Adobe ColdFusion (2018+) and CommandBox include built-in REPLs for terminal use, you can build your own programmatic version using the following core functions: [2, 4]

1. The Evaluation Engine

The most critical part of a REPL is the Eval step. CFML provides two primary ways to execute strings as code:

  • Evaluate(): Best for executing single expressions and returning a value.
  • Render(): (Lucee specific) Similar to Evaluate, but specifically designed to execute CFML tag or script code and return the generated output as a string. [5, 6] 

2. Building a Basic Web-Based REPL

A programmatic REPL usually consists of a simple loop (often via a form submission) that maintains state.

// 1. READ: Get input from a form or API
inputCode = form.myScript ?: "";
if (len(trim(inputCode))) {
    try {
        // 2. EVAL: Execute the code
        // Note: Evaluate() is powerful but dangerous with untrusted input
        result = evaluate(inputCode);
        
        // 3. PRINT: Output the result
        writeOutput("Result: " & result);
    } catch (any e) {
        writeOutput("Error: " & e.message);
    }
}
// 4. LOOP: Handled by the user submitting the form again

3. Advanced Implementation Details

To create a more robust "shell-like" experience:

  • Persistent State: To keep variables alive across multiple inputs, store a "context" structure in a persistent scope like Session or Application.
  • Capturing Console Output: If the code uses writeOutput(), you may need to use cfsavecontent to capture that output before it hits the main buffer.
  • Safety: Never expose a REPL to public users. It allows for arbitrary code execution, which can delete files or access sensitive server data.
  • Multi-line Support: For more complex scripts, you may need to detect if a block (like an if statement or function) is complete before evaluating, similar to how [CommandBox's REPLParser](https://community.ortussolutions.com/t/replparser-multiline-support/9559) works. [6, 7, 8] 

Summary of Tools

Feature [2, 3] Function/Tool Platform
Expression Eval Evaluate(string) Adobe & Lucee
Full Code Execution Render(string) Lucee Only
Terminal REPL cf.bat / cf.sh Adobe (2018+)
CLI REPL box repl CommandBox

References

Using workflows written in CFML to write and read REPL

To build a workflow in CFML that programmatically reads from and writes to a REPL, you need to treat the REPL as an external process. This is most effectively done using CommandBox, which provides a robust CLI and REPL environment for CFML. [1, 2] 

1. Using CommandBox via cfexecute

The standard way to interact with a REPL from a running CFML workflow (like a background task or a web request) is to use <cfexecute> or the execute() function to call the [CommandBox binary](https://modern-cfml.ortusbooks.com/intro/instructions-and-interpreters).

  • Writing to REPL: You can pass CFML code directly to the CommandBox repl command using the --code flag or by piping input.
  • Reading from REPL: The output of the command is captured in a variable for your workflow to process. [3, 4, 5] 

Example: Running a Snippet and Capturing the Result

// Define the CFML code you want the REPL to evaluate
replInput = "x = 10; y = 20; writeOutput(x + y);";
// Execute CommandBox REPL with the code
execute(
    name = "box", 
    arguments = "repl --code=""#replInput#""", 
    variable = "replOutput", 
    timeout = 10
);
// Read the result back into your workflow
writeOutput("The REPL returned: " & replOutput);

2. Interactive Workflows with Piping

If your workflow needs to chain multiple operations, you can use the cfml command in CommandBox. This allows you to [pipe data](https://commandbox.ortusbooks.com/usage/execution/cfml-functions) between CFML functions as if they were terminal commands.

  • Workflow logic: #listGetAt www.foo.com 2 . | #ucase | #reverse
  • Result: The REPL processes each step and passes the "Read" result of one to the "Eval" of the next. [6, 7] 

3. Asynchronous "Daemon" REPL

For a long-running workflow that needs to keep a REPL "warm" (to avoid startup overhead), consider using an Event Gateway or a persistent background thread. [8] 

  1. Start a process: Use java.lang.ProcessBuilder via CFML to open a persistent connection to the CommandBox shell.
  2. Write to Stream: Send commands to the process's OutputStream.
  3. Read from Stream: Use a separate CFML thread to constantly poll the InputStream for the REPL's response. [9, 10] 

4. Safety and Best Practices

  • Sanitisation: If the input for your REPL comes from an external source, treat it as unsafe. Programmatic REPLs can execute fileDelete() or access system environment variables.
  • Timeouts: Always set a timeout in your execute calls to prevent a "loop" in the REPL from hanging your entire server.
  • Context: Remember that code executed in a separate REPL process does not share the same variable scope (like Session or Request) as your main workflow unless you explicitly pass those values in. [11] 

References

Pass complex data (like a Struct) between your workflow and a CommandBox REPL

To pass complex data, such as a Struct or Array, between a CFML workflow and a REPL, the most reliable method is to use JSON serialisation. Since the REPL and your main application run in separate memory spaces, JSON acts as a universal bridge for data exchange.

1. Passing a Struct into the REPL (Write)

When calling the REPL, convert your CFML Struct into a JSON string and inject it into the command as a literal. CommandBox’s REPL is smart enough to interpret a JSON string as a native Struct if it's the first input to certain functions or assigned directly. [1, 2] 

// Your complex workflow data
userData = {
    "id": 123,
    "roles": ["admin", "editor"],
    "settings": { "theme": "dark" }
};
// Serialize to JSON (use single quotes for the shell command)
jsonInput = serializeJSON(userData);
// Build the REPL command
// Note: We assign the JSON string directly to a variable inside the REPL
replCommand = "data = #jsonInput#; writeOutput(data.roles[1]);";
execute(
    name = "box",
    arguments = "repl --code=""#replCommand#""",
    variable = "replResponse"
);
writeOutput("REPL processed role: " & replResponse); // "admin"

2. Getting a Struct back from the REPL (Read)

To read complex data back into your workflow, have the REPL print the result as JSON. You then use deserializeJSON() in your main workflow to turn that string back into a live CFML Struct. [3] 

// REPL code that performs logic and returns a new struct
replCode = "result = { 'status': 'success', 'timestamp': now() }; writeOutput(serializeJSON(result));";
execute(
    name = "box",
    arguments = "repl --code=""#replCode#""",
    variable = "rawJsonResponse"
);
// Read the complex data back into your workflow
if (isJSON(rawJsonResponse)) {
    finalData = deserializeJSON(rawJsonResponse);
    writeOutput("Status received: " & finalData.status);
}

Key Considerations for Data Integrity

  • Key Casing: Adobe ColdFusion typically converts struct keys to UPPERCASE during serialisation unless you quote the keys (e.g., {"name": "value"}).
  • Shell Escaping: Be careful with double quotes inside your JSON. When building the arguments string for execute(), ensure you escape quotes correctly so the shell doesn't break the command.
  • Performance: If you are passing very large datasets (multi-MB structs), the overhead of serialisation and shell execution will increase. For high-frequency workflows, consider writing the data to a temporary JSON file and having the REPL read that file instead of passing it as a command-line argument. [4, 5, 6, 7] 

Using temporary files to handle larger datasets between your workflow and the REPL

To handle larger datasets between your CFML workflow and a REPL, using temporary files is the most reliable method. This avoids shell character limits and prevents memory issues. [1] 

1. The Workflow: Writing to a Temp File

First, your main application serialises the data into a JSON file. Use getTempFile() to ensure a unique filename that won't collide with other processes. [2, 3] 

// 1. Prepare your large dataset
complexData = {
    "users": queryToArray( myLargeUserQuery ), // Assume 10k rows
    "metadata": { "source": "workflow_alpha", "processed": now() }
};
// 2. Create a unique temp file
tempFilePath = getTempFile( getTempDirectory(), "repl_data" );
// 3. WRITE: Save the JSON to the file
fileWrite( tempFilePath, serializeJSON( complexData ) );

2. The REPL: Reading the File

When you execute the REPL, pass the file path as a variable. The REPL code will then read the file from disk and deserialise it back into a native CFML object. [4, 5] 

// 4. Build the REPL script to READ the file
replCode = "
    data = deserializeJSON( fileRead('#tempFilePath#') );
    // Perform complex logic on the data
    resultCount = data.users.len();
    writeOutput( resultCount );
";
// 5. EXECUTE: Call CommandBox REPL
execute(
    name = "box",
    arguments = "repl --code=""#replCode#""",
    variable = "replOutput"
);

3. Cleaning Up

Because these files are stored in the system's temporary directory, they will eventually be cleared, but it is best practice to delete them manually once your workflow is finished to save disk space. [1, 6] 

// 6. Cleanup after reading the result
if ( fileExists( tempFilePath ) ) {
    fileDelete( tempFilePath );
}
writeOutput( "REPL processed #replOutput# records." );

Why use files instead of variables?

  • Memory Efficiency: Large strings in shell commands can lead to "Out of Memory" (OOM) errors or exceed operating system command-line length limits.
  • Data Integrity: Files eliminate the need for complex shell quoting and escaping of special characters in your JSON.
  • Persistent Context: If the REPL crashes, the data remains safely on disk for debugging or a retry attempt. [1, 7] 

References

CommandBox Task Runners to make these multi-step REPL workflows even cleaner

While a REPL is great for ad-hoc snippets, CommandBox Task Runners provide a more structured way to handle multi-step workflows. A Task Runner is a CFML component (.cfc) that runs directly from the command line, allowing you to pass complex arguments naturally and use built-in helpers for file and shell interaction. [1, 2, 3, 4]

1. Create the Task Runner (MyTask.cfc) [5]

Instead of cramming logic into a string for the REPL, you write a standard CFML function. You can create one by running task create --open in [CommandBox](https://commandbox.ortusbooks.com/task-runners). [2, 3, 6] 

/**
 * MyTask.cfc
 * Automates a workflow with complex data
 */
component {
    
    function run( string inputPath ) {
        // 1. READ: Load the large dataset from the file
        var data = deserializeJSON( fileRead( arguments.inputPath ) );
        
        print.greenLine( "Processing #data.users.len()# users..." );

        // 2. EVAL: Perform your workflow logic
        var result = {
            "processedCount": data.users.len(),
            "timestamp": now(),
            "status": "complete"
        };

        // 3. PRINT: Return the result as JSON for the calling workflow
        print.text( serializeJSON( result ) );
    }
}

2. Execute the Task from your Workflow [5]

In your main application, you call the task just like you did with the REPL, but it’s much cleaner because the logic is encapsulated in its own file. [7, 8] 


// Path to your Task Runner CFC
taskPath = expandPath( "./MyTask.cfc" );
tempDataFile = getTempFile( getTempDirectory(), "data" );

// Prepare and write data
fileWrite( tempDataFile, serializeJSON( myLargeStruct ) );

// Execute the task via CommandBox
execute(
    name = "box",
    arguments = "task run taskFile=#taskPath# inputPath=#tempDataFile#",
    variable = "rawResult"
);
// Process the structured return
workflowResult = deserializeJSON( rawResult );
writeOutput( "Workflow finished at: #workflowResult.timestamp#" );

Why Task Runners are better for workflows:

  • Portability: Tasks are self-contained in a CFC and can be dropped into any folder without being a full module.
  • Built-in Helpers: You get access to the print helper for formatted console output and filesystemUtil for easy path resolution.
  • Named Parameters: Unlike the REPL, tasks support [named parameters](https://commandbox.ortusbooks.com/task-runners/running-other-tasks), making it easy to pass file paths, IDs, or configuration flags.
  • Readability: Your code is written in a standard IDE with syntax highlighting and error checking rather than as a string inside an execute() call. [1, 3, 9, 10, 11] 

References

Scheduling these tasks to run automatically at specific intervals

To schedule CommandBox Task Runners at specific intervals, you have three primary approaches depending on whether you want to use the operating system, a background process (daemon), or the ColdFusion engine itself. [1] 

1. The Daemon Approach (Self-Scheduling)

For workflows that need to run continuously in the background without external dependencies, you can write your task as a daemon. This involves a while(true) loop and a sleep() command within the CFC. [2, 3] 

/**
 * ScheduledTask.cfc
 * Run: box task run taskFile=ScheduledTask.cfc
 */
component {
    function run() {
        try {
            while( true ) {
                print.blueLine( "Running workflow at #now()#..." );
                
                // INSERT YOUR WORKFLOW LOGIC HERE
                
                // Sleep for 5 minutes (300,000 milliseconds)
                sleep( 300000 );
            }
        } catch( any e ) {
            print.redLine( "Task interrupted: #e.message#" );
        }
    }
}

2. OS-Level Scheduling (Cron / Task Scheduler)

This is the most "production-ready" method for strictly timed intervals (e.g., every day at 2 AM). You simply tell your OS to execute the CommandBox binary and your specific task file. [3, 4, 5, 6] 

  • Linux (Crontab): Add a line to your crontab using crontab -e:
    0 2 * * * /usr/local/bin/box task run /path/to/MyTask.cfc
  • Windows (Task Scheduler): Create a new task that runs the box.exe program with the arguments task run taskFile=C:\path\to\MyTask.cfc. [7, 8, 9] 

3. CFML Engine Scheduling (cfschedule) [10] 

If you want to manage the schedule from within your web application's admin interface or code, you can use the native <cfschedule> tag or cfschedule() function to call the CommandBox CLI. [10, 11] 

cfschedule(
    action    = "update",
    task      = "HourlyWorkflow",
    operation = "HTTPRequest",
    url       = "http://localhost/run_my_task.cfm", // A script that runs the task
    interval  = "3600" // Every hour
);

Note: Your run_my_task.cfm file would then contain the execute() call to trigger the CommandBox task.

4. Advanced: ColdBox Scheduled Tasks

If you are using the [ColdBox Framework](https://coldbox.ortusbooks.com/digging-deeper/scheduled-tasks), you can use the built-in Async Scheduler to define tasks with a fluent, human-readable API. [1, 9, 12] 

// inside your Scheduler.cfc
task( "CleanTempFiles" )
    .call( function(){
        // CommandBox execution logic here
    } )
    .every( 1, "hours" )
    .delay( 5, "minutes" );

References
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The i18n Issue

Mike's Notes

This is a copy of the March issue of Ajabbi Research.

It is about the history of the effort to make Pipi available in any language, localisation, or script requested by users (i18n).

Ajabbi Research is published on SubStack on the first Friday of each month, and subscriptions are free.

Each issue is a broad historical overview of a research topic, serving as an index to dozens of previously posted related articles. There are now over 650 articles/posts.

This copy of the issue will be updated with additional information as it becomes available. Check the Last Updated date given below.

Eventually, each issue will be reused on the separate Ajabbi Research website as an introduction to a research area comprising multiple research projects.

Resources

References

  • SIL.
  • Unicode

Repository

  • Home > Ajabbi Research > Library >
  • Home > Handbook > 

Last Updated

03/04/2026

The i18n Issue

By: Mike Peters
Ajabbi Research: 6/03/2026

Mike is the inventor and architect of Pipi and the founder of Ajabbi.

This is the story of the effort to make Pipi available in any human language and script. The steps taken have been part of Pipi's development since 2005, spanning 5 versions.

The NZERN Pipi 2003-2005 Development Plan started it all.

Pipi 4 (2005-2008)

The story starts with Pipi 4. It was a big, successful system that supported community-driven Ecological Restoration in NZ. Here is a history of that Pipi version.

Initially, the large websites that Pipi generated were in English only.  Then, as botanical and zoological information was added, Latin, English, and Maori names were used. Eventually, provision for Chinese was planned to support the Chinese community-led conservation programmes. There were no separate language data structures in the 850-table Pipi 4 database; instead, some entities had additional columns for each language.

English

  • The 25,000 pages of websites that Pipi generated were initially in English.

Latin

  • Scientific names used in biological data were written in Latin.

Maori

  • Over time, it was realised that support for the Maori Language, Te Reo Maori, was required. To start, bilingual volunteers provided lists of words for regional areas, towns, etc.

Chinese

  • There was an Auckland-based Chinese Community-driven initiative to reach older residents who didn't speak English about conservation.

    Pipi 6 (2017-2019)

    When Pipi was rebuilt from memory, based on the limited experience with Pipi 4, foundational work was done to prepare Pipi for better multilingual support. This would require extra databases.

    Metadata using international codes was added to every database table to enable future language usage. The codes used were ISO 639-3, Country, Unicode, and CLDR/LDML

    ISO 639-3

    ISO 639 gives comprehensive provisions for the identification and assignment of language identifiers to individual languages, and for the creation of new language code elements or for the modification of existing ones (Terms of Reference of the ISO639/MA). - ISO 639-3

    *** 

    It defines three-letter codes for identifying languages. The standard was published by the International Organisation for Standardisation (ISO) on 1 February 2007. As of 2023, this edition of the standard has been officially withdrawn and replaced by ISO 639:2023.

    ISO 639-3 extends the ISO 639-2 alpha-3 codes with an aim to cover all known natural languages. The extended language coverage was based primarily on the language codes used in the Ethnologue (volumes 10–14) published by SIL International, which is now the registration authority for ISO 639-3.[2] It provides an enumeration of languages as complete as possible, including living and extinct, ancient and constructed, major and minor, written and unwritten. However, it does not include reconstructed languages such as Proto-Indo-European.

    ISO 639-3 is intended for use as metadata codes in a wide range of applications. It is widely used in computer and information systems, such as the Internet, in which many languages need to be supported. In archives and other information storage, it is used in cataloging systems, indicating what language a resource is in or about. The codes are also frequently used in the linguistic literature and elsewhere to compensate for the fact that language names may be obscure or ambiguous. Wikipedia

    Examples

    • Eng (English
    • Fra (French)

    ISO_3166-1_alpha-3

    ISO 3166-1 alpha-3 codes are three-letter country codes defined in ISO 3166-1, part of the ISO 3166 standard published by the International Organization for Standardization (ISO), to represent countries, dependent territories, and special areas of geographical interest. They allow a better visual association between the codes and the country names than the two-letter alpha-2 codes (the third set of codes is numeric and hence offers no visual association). They were first included as part of the ISO 3166 standard in its first edition in 1974. - Wikipedia

     Examples

    • ABW  (Aruba)
    • AFG  (Afghanistan)
    • AGO  (Angola)

    Unicode

    Unicode (also known as The Unicode Standard and TUS) is a character encoding standard maintained by the Unicode Consortium designed to support the use of text in all of the world's writing systems that can be digitized. Version 17.0[A] defines 159,801 characters and 172 scripts used in various ordinary, literary, academic and technical contexts. - Wikipedia

    Examples

    • Latn (Latin)
    • Lina (Linear B)
    • Hebr (Hebrew)

    CLDR/LDML

    The Common Locale Data Repository (CLDR) is a project of the Unicode Consortium to provide locale data in XML format for use in computer applications. CLDR contains locale-specific information that an operating system will typically provide to applications. CLDR is written in the Locale Data Markup Language (LDML). - Wikipedia

    Example

     <?xml version="1.0" encoding="UTF-8" ?>
    <ldml>
      
        <version number="1.1">ldml version 1.1</version>
        <generation date="2024-03-06"/>
        <language type="en"/>
        <territory type="US"/>
      
      <!-- other locale data sections follow -->
    </ldml>

    Localisation (L10N)

    Language localisation (or language localisation) is the process of adapting a product's translation to a specific country or region. It is the second phase of a larger process of product translation and cultural adaptation (for specific countries, regions, cultures or groups) to account for differences in distinct markets, a process known as internationalisation and localisation. - Wikipedia

    ***

    Pipi internally automatically stores and uses 3-letter language codes, 4-letter Unicode and 3-letter country codes to define Locales.

    Examples

    • eng-Latn-NZD (New Zealand English)
    • eng-Latn-USA (United States English)

    Customers can configure the options for their own websites.

    Examples

    • en-NZ
    • en-uk

    More information

    Pipi 7 (2020)

    Small, simple, static HTML mockups of websites were created to test how different languages could be used. Experiments with HTML and CSS were conducted to display text on a website in Left-to-Right (LTR) and Right-to-Left (RTL) word order.

    Pipi 8 (2021-2022)

    System-wide i18n and L10N namespaces were implemented throughout Pipi to enable reliable automation and rapid scaling across multiple languages.

    Pipi 9 (2023-2026)

    Joining up all the built systems to self-generate documentation and a front-end User Interface (UI).

    Experiments were conducted to determine how to integrate i18n support with Pipi's other features. It was confirmed that the Pipi core is written in British Standard English and checked by Grammarly.

    A source-target data model structure was created to store i18n scripts. It was greatly influenced by the system used by Wikipedia (MediaWiki) and OpenOffice.

    Experiments were done using 23 languages and writing scripts to test the CMS Engine (cms), data storage, UI layout, etc.

    String Translation

    Community translation will require a dedicated workspace.

    Account Settings

    Each Pipi is built in 1 language and script. Each account can have many languages. An account has many deployments, each in only one language. A deployment can have many workspaces.

    Localisation

    API Endpoints

    All API connections include a choice of API version and language/script.

    Scripts

    Noto from Google was chosen as the default font for Ajabbi due to the number of scripts it supports.

    KeyMan

    SIL provides an open-source KeyMan that enables keyboards for 2500 different languages to be added to websites. Pipi will use a Keyboard Engine (kyb) to provide this integration. This will be built as part of Pipi 10.

    Url Naming Pattern

    Many experiments were conducted to determine a URL structure that could accommodate websites in many languages. Wikipedia was the main influence.

    Examples

    • eng.example.com
    • example.com/eng/
    • en-uk.example.com
    • example.com/en-nz/

    Documentation

    Documentation and Learning material will need to be provided in many languages. The data models are ready for this. As the British English documentation is completed, it could be auto-translated into US English using Grammarly and into the 9 world languages using Google Translate. It would then need to be checked by volunteer users. This is speculative and will require trial and error to confirm.

    Language Prioritisation

    English > 9 world languages > 7000 local languages + localisation.

    Priority will be given to English, which will then serve as the source for translation into 9 world languages.

    • Arabic
    • Bhasa Indonesian
    • Chinese
    • French
    • German
    • Japanese
    • Hindi
    • Portugese
    • Russian
    • Spanish

    Carefully edited material in those languages can then be translated into any of the other 7,000 languages by volunteers in response to user requests.

      Model-driven UI

      The User Interface Description Language (UIDL) was an EU-funded project that was abandoned in 2010 after 10 years of excellent work. It was to enable accessibility on different screens and devices. The research results were reverse-engineered to build a User Interface Engine (usi) that would run in reverse to generate accessibility solutions for Pipi. The CSS Engine (css) replaced some redundant components of the UIDL project. Additional engines for localisation and personalisation were created.


      Pipi CMS Engine (cms)

      For a first teaching customer, a decision was made early on to autogenerate a separate website for each language (English, Māori, NZ Sign Language, and AAC picture language). This was the simplest solution for the CMS and the users.

      Creating UI for each natural language, including sign languages (i18n), requires user requests and volunteer testers.

      Sign Language

      The scheme was dreamed up to embed NZ Relay Video Interpreting on any webpage and in user workspaces. This is an ongoing experiment, driven by deaf people.

      Picture Language

      Professor Stephen Hawking used AAC via a computer-generated voice. There are many forms of AAC, including picture language. Providing this as a UI is being explored, with other AAC to follow. Important for the millions of people with Cerebral Palsy and Motor Neurone Disease.

      Invented Languages

      This system will be able to provide support for Klingon, Elvish, and other invented languages from books and movies, upon request and with volunteers prepared to do the work. This could be useful for fan communities.

      Dead Languages

      This system will be able to provide support for long-dead languages often studied by linguists and historians, such as Ancient Egyptian, Sumerian, Sanskrit, and Ancient Greek, upon request, with volunteers prepared to do the work. This could be useful for museums and faith communities.

      Workspace personalisation

      The workspace settings will eventually offer complete personalisation of the UI in other languages. This will use a personalisation form in account settings.

      Future Ajabbi Foundation Sponsorship

      Once Ajabbi has established ongoing sponsorship for Ortus for providing open-source BoxLang, the Ajabbi Foundation will generously sponsor open-source SIL KeyMan on an ongoing basis.

      Whats next

      Pipi 9 is available only in English. However, users can request any other language through their profile. Pipi 10 (2027-) will feature those multiple languages.

      The most useful and inspiring resource has been SIL Global.

      Dedication

      Every child has the right to be educated in the language of their people and of their birth. This is dedicated to those working tirelessly to record, strengthen or revive human languages.

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