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APL Core Library enables device makers to create their own "APL viewhost", bringing Alexa experiences with visual renderings to new devices or platforms using any programming language that can invoke C/C++ code.

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Introduction

The rendering of screen layouts at runtime for the Alexa Presentation Language is controlled by the APL Core Library, which is an abstract engine that manages not only APL document parsing and layout inflation, but also event handling, commands, and the rendering workflow. The APL Core Library interfaces with platform and language-specific APL "view hosts", which are responsible for performing the rendering in the platform or framework for which the view host was designed.

Consumers of the APL Core Library can create their own APL view host in order to create Alexa experiences with visual renderings on their device or platform in the programming language of their choice.

Architecture

                              APL Core Library

         +----------------------------------------------------------+
         | +---------------+  +----------------+ +----------------+ |
         | |               |  |                | |                | |
         | |     APL       |  |    Inflation   | |   Command      | |
         | |   Document    |  |    + Layout    | |   Processing   | |
         | |    Parsing    |  |    Management  | |                | |
         | |               |  |                | |                | |
         | +---------------+  +----------------+ +----------------+ |
         | +---------------+  +----------------+ +----------------+ |
         | |               |  |                | |                | |
         | |    Event      |  |     Data       | |    Viewport    | |
         | |   Handling    |  |    Binding     | |                | |
         | |               |  |                | |                | |
         | |               |  |                | |                | |
         | +---------------+  +----------------+ +----------------+ |
         | ........................................................ |
         | .:                                                    .: |
         | .:               RootContext & Content                .: |
         | .:                                                    .: |
         | .:''''''/''''''''''''''''''/''''\''''''''''''''''\''''.: |
         +--------+------------------+------+----------------+------+
                 /                  /        \                \
 +--------+     /   +--------+     /          \     +----+     \     +------+
 | OS 1   |    /    | OS 1   |    /            \    |OS 3|      \    |OS 4  |
 | App 1  |   /     | App 2  |   /              \   |App |       \   |App   |
 |        |  /      |        |  /                \  |    |        \  |      |
 +--------+-+----+  +--------+-+----+    +--------+-+----+  +------+-+------+
 |     OS1 Native|  | Cross Platform|    | Cross Platform|  |    OS4 Native |
 |     View Host |  | View Host     |    | View Host     |  |    View Host  |
 |               |  |               |    |               |  |               |
 +---------------+  +---------------+    +---------------+  +---------------+

Above is shown the high-level architecture of the APL Core Library, showing its interaction with a few possible view host implementations.

APL Document Parsing

APL Core is responsible for parsing and validating APL documents.

Inflation + Layout Management

APL Core is responsible for layout inflation into a Virtual DOM (with all its resources, styles and data-bound expressions evaluated)

Command Processing / Event Handling

After the APL Document is parsed, any commands specified in the document are inserted into a Command Sequence. Commands are exposed to the app via the Content object. APL Core is also responsible for handling and reporting contextual changes, UI, and other events.

Data Binding

APL Documents allow for the separation of presentation and data by providing a data binding mechanism that links document values to a data model.

Viewport

APL Core provides device viewport information such as theme, shape, height, width, and resolution.

RootContext and Content

The view hosts interface with APL Core through the RootContext and Content objects. The RootContext provides an interface for view host driven advancement of lifecycle events such as view hierarchy creation, text layout requests, change events, and command events. The Content represents the APL Document content.

View Host Guide

Separation of Concerns

In order to get a grasp on how to create a view host, it is good to be aware of the separation of concerns between the APL Core Library and the View Host. APL Core is a library that provides the document parsing, bookkeeping and logic associated with displaying and controlling a visual, auditory and tactile experience on a device. APL Core is platform-independent and operates on view abstractions. The view host is responsible for interfacing with APL Core to create and manage concrete views representing the visual experience.

View Host Responsibilities

Execution and Control Flow

The view host is in charge. The view host drives the execution and control flow and interfaces with the APL Core Library. Apart from a text measurement callback, there are no other callbacks from the Core to the view host. In all other cases, it is the view host that calls into the APL Core Library.

APL Document and Content

The view host obtains the APL document to be rendered and passes it to core as a parameter to Content::create(). The Content is passed as a parameter to RootContext::create.

APL RootContext

The view host creates a new APL RootContext, providing a viewport definition and the Content. see RootContext::create

Inflation

The APL Core parses the document and generates a virtual DOM hierarchy of APL Components. The view host constructs and renders concrete native views that represent the virtual DOM.

Run Loop

Execute a "run loop" that in a typical scenario, executes a single iteration of the loop per display frame. On every frame, the run loop does the following:

  • Calls RootContext::updateTime with a new timestamp for the frame.

  • Run Loop calls RootContext::hasEvent() - if true, it pops all events off of the queue and dispatches them appropriately.

  • Checks the RootContext for dirty properties and applies them to components.

Run Loop Pseudocode:

	BEGIN ON_NEW_FRAME
		Set current timestamp (RootContext::updateTime)
		WHILE (RootContext::hasEvent())
	 		RootContext::popEvent()
	 		Handle the Event
		END WHILE
		IF RootContext::isDirty THEN
	 		handleDirtyProps(RootContext::getDirty)
		END IF
	END ON_NEW_FRAME

Command Execution

An external source may invoke commands on the APL document. The view host passes calls RootContext::executeCommands to execute them and is informed of virtual DOM changes by the dirty properties set on components. The view host can cancel the command execution with RootContext::cancelCommands.

Keystroke Events

The view host is responsible for notifying APL Core of keystroke and input focus events.

Build Prerequisites

  • Supported Compilers:
    • GNU GCC and G++ version 5.3.1 or higher
    • LLVM and clang version 6.0.0 or higher
    • MSVC version 16 2019 or higher
  • CMake, version 3.5 or higher
  • For Windows, Ninja build system, 1.9.0 or higher, see: https://github.com/ninja-build/ninja
  • For Windows, the patch executable should be accessible on the system's PATH. The Windows build has been tested using the patch executable that ships with Git. The GnuWin32 patch executable is NOT recommended.

Building APL Core + Tests (Linux and Mac OS)

To build libaplcore.a and tests in your favorite C++ environment, do the following:

 source apl-dev-env.sh

 # Build the library
 apl-build-core

 # Run unit tests
 apl-test-core

 # Generate code coverage
 apl-coverage-core

 # Run memcheck
 apl-check-core

Mac Note: The CMake build generates the file CMakeCache.txt which contains paths to the system SDKROOT and build tools. New installations of XCode or Mac Command Line tools often modify the "Active Developer Directory" changing the location of the SDK. This may result in build failures. Most often this issue can be characterized by a failure to find the SYSROOT path.
An example of the path from CMakeCache.txt may look like: CMAKE_OSX_SYSROOT:PATH=/Library/Developer/CommandLineTools/SDKs/MacOSX13.0.sdk The "Active Developer Directory" can be identified as follows:

> xcode-select -p
/Library/Developer/CommandLineTools

To resolve, any of the following options are possible

  • To use the SYSROOT derived from the new "Active Developer Directory": Delete the build folder and regenerate the build. A "clean" build is not sufficient for CmakeCache.txt to be recreated.
  • To modify the "Active Developer Directory" to the desired SDK and tools paths Use xcode-select to set the new path or reset to the default.
  • To specify the explicit location of the SDK and tools rather than use the "Active Developer Directory" Modify the CMakeCache.txt SDK and tool paths. This option is not recommended, as it must be repeated any time the build folder is absent.

Building APL Core + Tests (Windows)

To build apl.lib and tests in a Windows or UWP environment, do the following:

 Start a VS Command Prompt (tested with "x64 Native Tools Command Prompt for VS 2019")
 C:\APLCoreEngine> mkdir build
 C:\APLCoreEngine> cd build
 C:\APLCoreEngine\build> cmake -G"Ninja" -DBUILD_TESTS=ON -DCOVERAGE=OFF -DCMAKE_BUILD_TYPE=Release ..
 C:\APLCoreEngine\build> ninja -j1

(If using the GnuWin32 patch.exe instead Git's patch.exe, the command prompt may need to run in Administrator Mode)

Running Tests

After the build succeeds, there are a number of test programs included in the build/test directory. For example, to validate the color parser, try:

 $ build/test/parseColor green

The most useful test program is parseLayout, which takes two data files as input: an APL document and an APL data file. The document will be processed and expanded into a component hierarchy by applying the data file.

Build Verification Using Docker

In order to verify that the build will work on various platforms, we have included Docker images for some of the more popular platforms. For instance, to verify that the build works on an Ubuntu 18.04 system, install Docker and run the following from the root directory of the APL Core Library project:

 $ docker build -f ubuntu18.04.Dockerfile  .

The Docker files for verifying the build on various platforms have the extension ".Dockerfile". They can be found by running the following from the root directory of the project:

 $ ls *.Dockerfile

For more info on installing and configuring Docker, see: https://www.docker.com/get-started

Global configuration

Tracing

In order to compile core tracing support use TRACING cmake parameter:

$ cmake -DTRACING=ON

Memory debugging

To build lib with memory debugging support use:

$ cmake -DDEBUG_MEMORY_USE=ON

Paranoid build

In order to build library with -Werror use:

$ cmake -DWERROR=ON

Alpha features

An Alpha feature may become part of the APL specification in a future release. These features are made available before the specification has finalized to allow for early experimentation with the features. Early adopters should expect that for alpha features that are released, APIs and data structures are likely to change when the specification is finalized.

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APL Core Library enables device makers to create their own "APL viewhost", bringing Alexa experiences with visual renderings to new devices or platforms using any programming language that can invoke C/C++ code.

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