From 04cede8e6e693ff1ad5d93dc2c4449a07c40ab96 Mon Sep 17 00:00:00 2001
From: Marcus Fritzsch <marcus_fritzsch@mentor.com>
Date: Thu, 14 Sep 2017 14:04:51 +0200
Subject: [PATCH] doc: convert asciidoc to md

Signed-off-by: Marcus Fritzsch <marcus_fritzsch@mentor.com>
---
 doc/CMakeLists.txt       |   2 +-
 doc/WindowManagerTMC.md  | 549 +++++++++++++++++++++++++++++++++++++++++++++++
 doc/WindowManagerTMC.txt | 488 -----------------------------------------
 3 files changed, 550 insertions(+), 489 deletions(-)
 create mode 100644 doc/WindowManagerTMC.md
 delete mode 100644 doc/WindowManagerTMC.txt

diff --git a/doc/CMakeLists.txt b/doc/CMakeLists.txt
index 5dcd396..eb50675 100644
--- a/doc/CMakeLists.txt
+++ b/doc/CMakeLists.txt
@@ -1,4 +1,4 @@
 install(
-   FILES ${CMAKE_PROJECT_NAME}.txt
+   FILES ${CMAKE_PROJECT_NAME}.md
    DESTINATION ${CMAKE_INSTALL_DOCDIR}
    COMPONENT "development")
diff --git a/doc/WindowManagerTMC.md b/doc/WindowManagerTMC.md
new file mode 100644
index 0000000..8294186
--- /dev/null
+++ b/doc/WindowManagerTMC.md
@@ -0,0 +1,549 @@
+Introduction
+============
+
+This WindowManager implements simple layout switching of applications on
+multiple layers and with different layer layouts.
+
+Intended audience
+-----------------
+
+This documentation is intended for developers and system integrators who
+need to know, how the window manager works and how it is to be used.
+
+Scope of this Document
+----------------------
+
+This document covers the window manager that was implemented for TMC and
+delivered to the Automotive Grade Linux (AGL) project. It includes its
+implementation details, concepts of operation, configuration and usage.
+
+It does not include
+
+-   documentation of the underlying architecture, see
+    [HMI-Framework](https://wiki.automotivelinux.org/hmiframework).
+
+-   documentation of the AGL application framework and its technologies,
+    see [AGL Application
+    Framework](https://wiki.automotivelinux.org/agl-distro/app-framework).
+
+It is highly recommended to have a good understanding of these documents
+and projects before using the window manager.
+
+Known Issues
+------------
+
+Currently there are a couple of known issues:
+
+-   Weston seems not to redraw the screen correctly. When the window
+    manager makes scene changes in quick succession, Weston seems not to
+    redraw the screen correctly and also not send wl\_surface::enter
+    events, which in turn leaves applications "dead" - i.e. not
+    rendering or showing up. We developed a simple secondary
+    ivi-controller client application **redraw\_fixer** (See
+    [redraw\_fixer](#_redraw_fixer) for more) that listens for specific
+    scene-change events and issues other commands that should prompt a
+    correct redraw - however, this does not work in all instances.
+
+-   Only single-surface Qt applications are support through the
+    AFBClient library. This is a limitation of how Qt creates surface
+    IDs for the ivi-application interface.
+
+External libraries
+------------------
+
+This project includes a copy of version 2.1.1 the excellent [C++11 JSON
+library by Niels Lohmann](https://github.com/nlohmann/json).
+
+Client Library
+--------------
+
+A client library implementation that internally uses the *libafbwsc*, is
+provided in the subdirectory `client-lib/` with its own documentation
+directory.
+
+The client library is built together with the window manager itself.
+
+Concepts
+========
+
+The window manager implements a couple of concepts in order to allow
+efficient implementation.
+
+Layers
+------
+
+Layers are entities that are stacked on top of each other. Each layer
+has an ID which is used for the ivi-controller interface, but this ID
+also implicitly specifies its stacking order, from lowest to highest.
+
+Layers are always full-screen. We do not use layer dimensions as a way
+to setup the scene, rather - each layer has a layout attached to it,
+which specifies an area that is used by surfaces to draw on.
+
+Additionally, layers will generally leave surfaces on below layers
+activated, and only disable surfaces on layers the are above the
+currently used layer.
+
+It is possible to deactivate these surfaces on lower layers explicitly
+using the `DeactivateSurface` API call.
+
+Surfaces
+--------
+
+Surfaces are *placed* on layers according to their name. The surface
+will then be resized to dimensions, according to the layer’s layout
+configuration.
+
+Binding API
+===========
+
+The binding API consists of a couple of AFB *verbs* - that is; function
+calls to the Window Manager.
+
+Verbs (Functions)
+-----------------
+
+Each function returns a reply containing at least a failed or successful
+result of the call, additionally, when calls return something, it is
+noted. The notation used has the following meaning:
+
+    FunctionName(argument_name: argument_type)[: function_return_type]
+
+Where the return type may be omitted if it is void.
+
+-   `RequestSurface(drawing_name: string): int` Request a surface ID for
+    the given name. This name and ID association will live until the
+    surface is destroyed (or e.g. the application exits). Each surface
+    that is managed by the window manager needs to call this function
+    first!
+
+-   `ActivateSurface(drawing_name: string)` This function requests the
+    activation of a surface. It usually is not called by the
+    application, but rather by the application framework or
+    the HomeScreen.
+
+-   `DeactivateSurface(drawing_name: string)` Request deactivation of
+    a surface. This function is not usually called by applications
+    themselves, but rather by the application framework or
+    the HomeScreen.
+
+-   `EndDraw(drawing_name: string)` Signals the window manager, that the
+    surface is finished drawing. This is useful for consistent
+    flicker-free layout switches, see the Architecture document
+    for details.
+
+There are a couple of non-essential (mostly for debugging and
+development) API calls:
+
+-   `list_drawing_names(): json` List known surface *name* to
+    *ID* associations.
+
+-   `ping()` Ping the window manager. Does also dispatch pending events
+    if any.
+
+-   `debug_status(): json` Returns a json representation of the current
+    layers and surfaces known to the window manager. This represents the
+    wayland-ivi-extension object’s properties.
+
+-   `debug_surfaces(): json` Returns a json representation of all
+    surfaces known to the window manager. This represents the
+    wayland-ivi-extension properties of the surfaces.
+
+-   `debug_layers(): json` Returns the current layer configuration, as
+    configured through *layers.json*.
+
+-   `debug_terminate()` Terminates the afb-daemon running the window
+    manager binding, if the environment variable
+    `WINMAN_DEBUG_TERMINATE` is set.
+
+Events
+------
+
+The window manager broadcasts certain events (to all applications) that
+signal information on the state of the surface regarding the current
+layout.
+
+-   `Active(drawing_name: string)` Signal that the surface with the name
+    `drawing_name` is now active.
+
+-   `Inactive(drawing_name: string)` Signal that the surface with the
+    name `drawing_name` is now inactive. This usually means, the layout
+    got changed, and the surface is now considered inactive
+    (or sleeping).
+
+-   `Visible(drawing_name: string)` Signal applications, that the
+    surface with name `drawing_name` is now visible.
+
+-   `Invisible(drawing_name: string)` Signal applications that the
+    surface with name `drawing_name` is now invisible.
+
+-   `SyncDraw(drawing_name: string)` Signal applications, that the
+    surface with name `drawing_name` needs to redraw its content - this
+    usually is sent when the surface geometry changed.
+
+-   `FlushDraw(drawing_name: string)` Signal to applications, that the
+    surface with name `drawing_name` can now be swapped to its newly
+    drawn content as the window manager is ready to activate a new
+    layout (i.e. a new surface geometry).
+
+Binding API Usage
+-----------------
+
+For a detailed description on how the binding API is supposed to be
+used, refer to the Architecture document.
+
+Configuration
+=============
+
+The window manager is configured with the *layers.json* configuration
+file, by default it is searched in `/etc/layers.json` but through the
+use of the environment variable `LAYERS_JSON` the WM can be instructed
+to use different file. Note, that the WM will not run unless this
+configuration is found and valid.
+
+A sample configuration is provided with the window manager
+implementation, this sample is installed to /etc/layers.json.
+
+Configuration Items
+-------------------
+
+This section describes configuration items available through
+`layers.json`. It will do this, by first providing an example, and then
+going into its components.
+
+### main\_surface
+
+    "main_surface": {
+       "surface_role": "HomeScreen",
+    },
+
+The `main_surface` object describes a surface that will internally be
+treated as the main surface - usually this mean *HomeScreen*. The only
+special handling this surface receives, is that it is not allowed to
+deactivate it. Placement of this surface on an layer is done by the
+other configuration described below.
+
+-   `surface_role` this configuration item specifies the name of the
+    main surface. Set this to e.g. `HomeScreen`.
+
+### mappings
+
+This configuration item is a list of surface-name to layer mappings.
+
+#### surface to layer mapping
+
+    "mappings": [
+       {
+          "role": "^HomeScreen$",
+          "name": "HomeScreen",
+          "layer_id": 1000,
+          "area": { "type": "full" },
+       },
+       {
+          "role": "^App.*",
+          "name": "apps",
+          "layer_id": 1001,
+          "area": { "type": "rect",
+                    "rect": { "x": 0,
+                              "y": 100,
+                              "width": -1,
+                              "height": -201 } },
+          "split_layouts": []
+       }
+    ]
+
+Each mapping defines the following items to map corresponding surfaces
+to a layer.
+
+-   `role` defines a regular expression that application drawing names
+    are matched against. If applications match tis regular expression,
+    the surface will be visible on this layer.
+
+-   `name` is just a name definition for this layer, it has no
+    functional use apart from identifying a layer with a name.
+
+-   `layer_id` specifies which ID this layer will use.
+
+-   `area` is an object that defines the area assigned to surfaces.
+
+-   `split_layouts` is an optional item, that - if present - defines a
+    number of possible split-screen layouts for this layer.
+
+#### Area
+
+Areas can be either `full` or `rect`, whereas `full` means a full-screen
+layer, this is mostly useful for the main\_surface or HomeScreen layer.
+`rect` declares a layer drawing area specified as a rectangle with start
+coordinates `x` and `y` as well as its dimensions `width` and `height`.
+
+The dimensions can be specified relative to the screen dimensions. For
+this negative values for width and height mus be used.
+
+For example, a full-screen surface can have the following `rect`
+definition:
+
+    "rect": { "x": 0,
+              "y": 0,
+              "width": -1,
+              "height": -1 }
+
+A surface that leaves a 200pixel margin on the top and bottom can use
+the following `rect` definition:
+
+    "rect": { "x": 0,
+              "y": 200,
+              "width": -1,
+              "height": -401 }
+
+So the expression for the actual surface dimensions when using
+screen-size-relative values will be:
+
+    actual_width = screen_width + 1 + width
+    actual_height = screen_height + 1 + height
+
+Or in other words, to leave an `N` wide border around a surface, the
+actual value in the dimension configuration needs to be `-N - 1`, and
+appropriate offsets need to be set for `x` and `y`.
+
+#### split\_layouts
+
+This configuration item allows the specification of split-screen layouts
+on layers for certain surfaces.
+
+A split screen layout always has a *main* surface and a *sub* surface.
+In order to enter a split screen layout, first the *main* surface of the
+layout must be activated, and then the *sub* surface. In order to
+disable the split layout, one of the two participating surface must be
+deactivated (or a surface on a layer below the current one must be
+activated).
+
+    "split_layouts": [
+       {
+          "name": "Media Player",
+          "main_match": "^App MPlayer Main$",
+          "sub_match": "^App MPlayer Sub",
+       }
+    ]
+
+A split layout object has the following attributes:
+
+-   `name` defines its name, it has no actual function other then a way
+    to identify this split layout.
+
+-   `main_match` is a regular expression that matches for the *main*
+    surface of this split layout.
+
+-   `sub_match` is a regular expression that matches for the *sub*
+    surface of this layout.
+
+In the above example only the surface with drawing name
+`App MPlayer Main` will be used as the *main* surface, but all surfaces
+that begin with `App MPlayer Sub` can be used as a *sub* surface for
+this layout.
+
+The names must still match the layer’s role match!
+
+Building and Running
+====================
+
+Dependencies
+------------
+
+This project is intended to be build with the 4.0 release of AGL.
+
+Build dependencies are as follows:
+
+-   afb-daemon &gt;= 1.0
+
+-   libsystemd &gt;= 222
+
+-   wayland-client &gt;= 1.11
+
+-   cmake &gt;= 3.6.1
+
+Build Configuration
+-------------------
+
+Use cmake to configure a build tree:
+
+    mkdir build
+    cd build
+    cmake ..
+    make
+    [sudo] make install
+
+A couple of build options to configure the build are available:
+
+-   `ENABLE_DEBUG_OUTPUT:BOOL` Compiles including very verbose debug
+    output from the window manager, use --verbose three times on an
+    afb-daemon instance to see the debug messages.
+
+-   `ENABLE_SCOPE_TRACING:BOOL` Enables a simple scope tracing mechanism
+    used for a rather small portion of the window manager code. However,
+    it is used quite extensively in the AFBClient implementation.
+
+By default these options will be disabled.
+
+Utilities
+=========
+
+With the actual window manager implementation, two general utilities are
+provided.
+
+wm-request
+----------
+
+A shell script, that wraps `afb-client-demo` and issues commands to the
+window manager using the AFB exposed API. It will call synchronously to
+the WM, and output any events that are happening in the meantime.
+Replies are printed to stdout using an failed/success annotation and a
+dump of the actual json reply from the AFB. When found on the system, it
+will use `pygmentize` to apply syntax highlighting to the returned JSON.
+
+### Examples
+
+    $ wm-request list_drawing_names
+    ON-REPLY 1:winman/list_drawing_names: OK
+    {
+      "response":{
+        "App1":1,
+        "App2":2,
+        "HomeScreen":3,
+        "OnScreen":4
+      },
+      "jtype":"afb-reply",
+      "request":{
+        "status":"success",
+        "info":"success"
+      }
+    }
+    $ wm-request activatesurface App1
+    ON-REPLY 1:winman/activatesurface: OK
+    {
+      "response":{
+      },
+      "jtype":"afb-reply",
+      "request":{
+        "status":"success",
+        "info":"success"
+      }
+    }
+    $ wm-request activatesurface AppThatDoesNotExist
+    ON-REPLY 1:winman/activatesurface: ERROR
+    {
+      "jtype":"afb-reply",
+      "request":{
+        "status":"failed",
+        "info":"Surface does not exist"
+      }
+    }
+
+redraw\_fixer
+-------------
+
+This utility is intended to be ran alongside the compositor, it will
+listen for certain events regarding surfaces, and issue a couple of
+other commands, to hopefully trigger a redraw of the surface in the
+compositor.
+
+It will print messages for each acted-upon event, and exit when the
+compositor exits.
+
+Implementation Notes
+====================
+
+The window manager is implemented as a app-framework-binder binding.
+That means, the build produces one shared object that exports a binding
+interface.
+
+Binding code generation
+-----------------------
+
+The binding API is rather simple; functions receive a json object
+describing arguments and return a json object describing the result or
+an error. In order to simplify development, the
+`generate-binding-glue.py` script was added, that contains a description
+of the API as a python dictionary. This script generates the header
+`afb_binding_api.hpp` and the afb binding functions as
+`afb_binding_glue.inl`. Where the latter is included in `main.cpp`.
+
+Each function for the AFB binding that is generated does the following:
+
+-   Lock the binding mutex, so that we serialize all access to
+    the binding.
+
+-   Do some debug logging (if wanted).
+
+-   Check the binding state, i.e. the compositor might have exited
+    unexpectedly at which point it would not make sense to continue.
+
+-   Extract the arguments from the json object that is provided (doing
+    some primitive type checking).
+
+-   Call the afb\_binding\_api method corresponding to this binding
+    function
+
+-   Check the afb\_binding\_api’s function return value, log an error
+    state and return the result to the afb request.
+
+The generated functions do also check for any "loose" exception that
+comes out of the afb\_binding\_api call (which in turn might call the
+actual non-trivial implementation in `App`). However, **IF** an
+exception is thrown and not handled inside the afb\_binding\_call, that
+internal state of the window manager might be broken at this time (hence
+the talkative error log).
+
+Structure
+---------
+
+The implementation is loosely split across the following source files:
+
+-   `main.cpp`: The program entry point as used by the afb-daemon. This
+    file defines the afbBindingV2 symbol tat is used by the afb-daemon
+    in order to load a binding. It also defines the wayland fd event
+    dispatcher and some globals to be used (as context for the afb calls
+    we receive).
+
+-   `afb_binding_api.cpp`: The implementation of the afb
+    binding functions. The actual functions are generated by
+    `generate-binding-glue.py` which generates a **.inl** file that is
+    included by `main.cpp`.
+
+-   `app.cpp` / `app.hpp`: This is the main application
+    logic implementation.
+
+-   `config.cpp` / `config.hpp`: Very simple configuration
+    item interface.
+
+-   `controller_hooks.hpp`: hook functions called by the wayland
+    controller to call into the App instance. Only a very limited number
+    of events are passed to the Application, which allowed the usage of
+    such a simple interface.
+
+-   `json_helper.cpp` / `json_helper.hpp`: Smaller json related
+    helper functions.
+
+-   `layers.cpp` / `layers.hpp`: Actually hold all the data from
+    layers.json configuration, do some transformations and service the
+    App implementation.
+
+-   `layout.cpp` / `layout.hpp`: Very simple layout state for the
+    implementation of split layouts and tracking of the
+    surfaces involved.
+
+-   `policy.hpp`: PolicyManager implementation stub. Gets passed the
+    current and new layout on layout switch and can decide upon it being
+    valid or not.
+
+-   `result.hpp`: Simple result class around
+    `std::experimental::optional` that additionally can hold a
+    `char const *` to describe the error.
+
+-   `util.cpp` / `util.hpp`: general utility functions and structs - and
+    preprocessor definitions (e.g. `log*()` to AFB logging functions.
+
+-   `wayland.cpp` / `wayland.hpp`: A C++ object-oriented
+    libwayland-client wrapper. It is instanced in `main.cpp` and handles
+    all our wayland needs.
+
+
diff --git a/doc/WindowManagerTMC.txt b/doc/WindowManagerTMC.txt
deleted file mode 100644
index 6446396..0000000
--- a/doc/WindowManagerTMC.txt
+++ /dev/null
@@ -1,488 +0,0 @@
-= WindowManagerTMC
-:doctype: book
-:toc:
-:icons:
-:data-uri:
-:lang: en
-:encoding: utf-8
-
-== Introduction
-This WindowManager implements simple layout switching of applications on
-multiple layers and with different layer layouts.
-
-=== Intended audience
-This documentation is intended for developers and system integrators
-who need to know, how the window manager works and how it is to be used.
-
-=== Scope of this Document
-This document covers the window manager that was implemented for TMC and
-delivered to the Automotive Grade Linux (AGL) project. It includes its
-implementation details, concepts of operation, configuration and usage.
-
-It does not include
-
-* documentation of the underlying architecture, see
-  https://wiki.automotivelinux.org/hmiframework[HMI-Framework].
-* documentation of the AGL application framework and its technologies,
-  see https://wiki.automotivelinux.org/agl-distro/app-framework[AGL
-  Application Framework].
-
-It is highly recommended to have a good understanding of these documents
-and projects before using the window manager.
-
-=== Known Issues
-Currently there are a couple of known issues:
-
-* Weston seems not to redraw the screen correctly. When the window
-  manager makes scene changes in quick succession, Weston seems not to
-  redraw the screen correctly and also not send wl_surface::enter
-  events, which in turn leaves applications "dead" - i.e. not rendering
-  or showing up. We developed a simple secondary ivi-controller client
-  application *redraw_fixer* (See <<_redraw_fixer,redraw_fixer>> for more)
-  that listens for specific scene-change events and issues other commands
-  that should prompt a correct redraw - however, this does not work in
-  all instances.
-* Only single-surface Qt applications are support through the AFBClient
-  library. This is a limitation of how Qt creates surface IDs for the
-  ivi-application interface.
-
-=== External libraries
-This project includes a copy of version 2.1.1 the excellent
-https://github.com/nlohmann/json[C++11 JSON library by Niels Lohmann].
-
-=== Client Library
-A client library implementation that internally uses the _libafbwsc_, is
-provided in the subdirectory `client-lib/` with its own documentation
-directory.
-
-The client library is built together with the window manager itself.
-
-== Concepts
-The window manager implements a couple of concepts in order to allow
-efficient implementation.
-
-=== Layers
-Layers are entities that are stacked on top of each other. Each layer
-has an ID which is used for the ivi-controller interface, but this ID
-also implicitly specifies its stacking order, from lowest to highest.
-
-Layers are always full-screen. We do not use layer dimensions as a way
-to setup the scene, rather - each layer has a layout attached to it,
-which specifies an area that is used by surfaces to draw on.
-
-Additionally, layers will generally leave surfaces on below layers
-activated, and only disable surfaces on layers the are above the
-currently used layer.
-
-It is possible to deactivate these surfaces on lower layers explicitly
-using the `DeactivateSurface` API call.
-
-=== Surfaces
-Surfaces are _placed_ on layers according to their name. The surface
-will then be resized to dimensions, according to the layer's layout
-configuration.
-
-== Binding API
-The binding API consists of a couple of AFB _verbs_ - that is; function
-calls to the Window Manager.
-
-=== Verbs (Functions)
-Each function returns a reply containing at least a failed or successful
-result of the call, additionally, when calls return something, it is
-noted. The notation used has the following meaning:
-
-------
-FunctionName(argument_name: argument_type)[: function_return_type]
-------
-
-Where the return type may be omitted if it is void.
-
-* `RequestSurface(drawing_name: string): int`
-  Request a surface ID for the given name. This name and ID association
-  will live until the surface is destroyed (or e.g. the application
-  exits). Each surface that is managed by the window manager needs to
-  call this function first!
-* `ActivateSurface(drawing_name: string)`
-  This function requests the activation of a surface. It usually is not
-  called by the application, but rather by the application framework or
-  the HomeScreen.
-* `DeactivateSurface(drawing_name: string)`
-  Request deactivation of a surface. This function is not usually called
-  by applications themselves, but rather by the application framework or
-  the HomeScreen.
-* `EndDraw(drawing_name: string)`
-  Signals the window manager, that the surface is finished drawing. This
-  is useful for consistent flicker-free layout switches, see the
-  Architecture document for details.
-
-There are a couple of non-essential (mostly for debugging and
-development) API calls:
-
-* `list_drawing_names(): json`
-  List known surface _name_ to _ID_ associations.
-* `ping()`
-  Ping the window manager. Does also dispatch pending events if any.
-* `debug_status(): json`
-  Returns a json representation of the current layers and surfaces known
-  to the window manager. This represents the wayland-ivi-extension
-  object's properties.
-* `debug_surfaces(): json`
-  Returns a json representation of all surfaces known to the window
-  manager. This represents the wayland-ivi-extension properties of the
-  surfaces.
-* `debug_layers(): json`
-  Returns the current layer configuration, as configured through
-  _layers.json_.
-* `debug_terminate()`
-  Terminates the afb-daemon running the window manager binding, if the
-  environment variable `WINMAN_DEBUG_TERMINATE` is set.
-
-=== Events
-The window manager broadcasts certain events (to all applications) that
-signal information on the state of the surface regarding the current
-layout.
-
-* `Active(drawing_name: string)`
-  Signal that the surface with the name `drawing_name` is now active.
-* `Inactive(drawing_name: string)`
-  Signal that the surface with the name `drawing_name` is now inactive.
-  This usually means, the layout got changed, and the surface is now
-  considered inactive (or sleeping).
-* `Visible(drawing_name: string)`
-  Signal applications, that the surface with name `drawing_name` is now
-  visible.
-* `Invisible(drawing_name: string)`
-  Signal applications that the surface with name `drawing_name` is now
-  invisible.
-* `SyncDraw(drawing_name: string)`
-  Signal applications, that the surface with name `drawing_name` needs
-  to redraw its content - this usually is sent when the surface geometry
-  changed.
-* `FlushDraw(drawing_name: string)`
-  Signal to applications, that the surface with name `drawing_name` can
-  now be swapped to its newly drawn content as the window manager is
-  ready to activate a new layout (i.e. a new surface geometry).
-
-=== Binding API Usage
-For a detailed description on how the binding API is supposed to be
-used, refer to the Architecture document.
-
-== Configuration
-The window manager is configured with the _layers.json_ configuration
-file, by default it is searched in `/etc/layers.json` but through the
-use of the environment variable `LAYERS_JSON` the WM can be instructed
-to use different file. Note, that the WM will not run unless this
-configuration is found and valid.
-
-A sample configuration is provided with the window manager
-implementation, this sample is installed to /etc/layers.json.
-
-=== Configuration Items
-This section describes configuration items available through
-`layers.json`. It will do this, by first providing an example, and then
-going into its components.
-
-==== main_surface
-------
-"main_surface": {
-   "surface_role": "HomeScreen",
-},
-------
-
-The `main_surface` object describes a surface that will internally be
-treated as the main surface - usually this mean _HomeScreen_. The only
-special handling this surface receives, is that it is not allowed to
-deactivate it. Placement of this surface on an layer is done by the
-other configuration described below.
-
-* `surface_role` this configuration item specifies the name of the main
-  surface. Set this to e.g. `HomeScreen`.
-
-==== mappings
-This configuration item is a list of surface-name to layer mappings.
-
-===== surface to layer mapping
-------
-"mappings": [
-   {
-      "role": "^HomeScreen$",
-      "name": "HomeScreen",
-      "layer_id": 1000,
-      "area": { "type": "full" },
-   },
-   {
-      "role": "^App.*",
-      "name": "apps",
-      "layer_id": 1001,
-      "area": { "type": "rect",
-                "rect": { "x": 0,
-                          "y": 100,
-                          "width": -1,
-                          "height": -201 } },
-      "split_layouts": []
-   }
-]
-------
-
-Each mapping defines the following items to map corresponding surfaces
-to a layer.
-
-* `role` defines a regular expression that application drawing names are
-  matched against. If applications match tis regular expression, the
-  surface will be visible on this layer.
-* `name` is just a name definition for this layer, it has no functional use
-  apart from identifying a layer with a name.
-* `layer_id` specifies which ID this layer will use.
-* `area` is an object that defines the area assigned to surfaces.
-* `split_layouts` is an optional item, that - if present - defines a
-  number of possible split-screen layouts for this layer.
-
-===== Area
-Areas can be either `full` or `rect`, whereas `full` means a full-screen
-layer, this is mostly useful for the main_surface or HomeScreen layer.
-`rect` declares a layer drawing area specified as a rectangle with
-start coordinates `x` and `y` as well as its dimensions `width` and
-`height`.
-
-The dimensions can be specified relative to the screen dimensions. For
-this negative values for width and height mus be used.
-
-For example, a full-screen surface can have the following `rect`
-definition:
-
-------
-"rect": { "x": 0,
-          "y": 0,
-          "width": -1,
-          "height": -1 }
-------
-
-A surface that leaves a 200pixel margin on the top and bottom can use
-the following `rect` definition:
-
-------
-"rect": { "x": 0,
-          "y": 200,
-          "width": -1,
-          "height": -401 }
-------
-
-So the expression for the actual surface dimensions when using
-screen-size-relative values will be:
-
-------
-actual_width = screen_width + 1 + width
-actual_height = screen_height + 1 + height
-------
-
-Or in other words, to leave an `N` wide border around a surface, the
-actual value in the dimension configuration needs to be `-N - 1`, and
-appropriate offsets need to be set for `x` and `y`.
-
-===== split_layouts
-This configuration item allows the specification of split-screen layouts
-on layers for certain surfaces.
-
-A split screen layout always has a _main_ surface and a _sub_
-surface. In order to enter a split screen layout, first the _main_
-surface of the layout must be activated, and then the _sub_ surface. In
-order to disable the split layout, one of the two participating surface
-must be deactivated (or a surface on a layer below the current one
-must be activated).
-
-------
-"split_layouts": [
-   {
-      "name": "Media Player",
-      "main_match": "^App MPlayer Main$",
-      "sub_match": "^App MPlayer Sub",
-   }
-]
-------
-
-A split layout object has the following attributes:
-
-* `name` defines its name, it has no actual function other then a way to
-  identify this split layout.
-* `main_match` is a regular expression that matches for the _main_
-  surface of this split layout.
-* `sub_match` is a regular expression that matches for the _sub_ surface
-  of this layout.
-
-In the above example only the surface with drawing name
-`App MPlayer Main` will be used as the _main_ surface, but all surfaces
-that begin with `App MPlayer Sub` can be used as a _sub_ surface for
-this layout.
-
-.Note
-******
-The names must still match the layer's role match!
-******
-
-== Building and Running
-
-=== Dependencies
-This project is intended to be build with the 4.0 release of AGL.
-
-Build dependencies are as follows:
-
-* afb-daemon >= 1.0
-* libsystemd >= 222
-* wayland-client >= 1.11
-* cmake >= 3.6.1
-
-=== Build Configuration
-Use cmake to configure a build tree:
-
---------
-mkdir build
-cd build
-cmake ..
-make
-[sudo] make install
---------
-
-A couple of build options to configure the build are available:
-
-* `ENABLE_DEBUG_OUTPUT:BOOL` Compiles including very verbose debug
-  output from the window manager, use --verbose three times on an
-  afb-daemon instance to see the debug messages.
-* `ENABLE_SCOPE_TRACING:BOOL` Enables a simple scope tracing mechanism
-  used for a rather small portion of the window manager code. However,
-  it is used quite extensively in the AFBClient implementation.
-
-By default these options will be disabled.
-
-== Utilities
-With the actual window manager implementation, two general utilities are
-provided.
-
-=== wm-request
-A shell script, that wraps `afb-client-demo` and issues commands to the
-window manager using the AFB exposed API. It will call synchronously to
-the WM, and output any events that are happening in the meantime.
-Replies are printed to stdout using an failed/success annotation and a
-dump of the actual json reply from the AFB. When found on the system, it
-will use `pygmentize` to apply syntax highlighting to the returned JSON.
-
-==== Examples
-
-------
-$ wm-request list_drawing_names
-ON-REPLY 1:winman/list_drawing_names: OK
-{
-  "response":{
-    "App1":1,
-    "App2":2,
-    "HomeScreen":3,
-    "OnScreen":4
-  },
-  "jtype":"afb-reply",
-  "request":{
-    "status":"success",
-    "info":"success"
-  }
-}
-$ wm-request activatesurface App1
-ON-REPLY 1:winman/activatesurface: OK
-{
-  "response":{
-  },
-  "jtype":"afb-reply",
-  "request":{
-    "status":"success",
-    "info":"success"
-  }
-}
-$ wm-request activatesurface AppThatDoesNotExist
-ON-REPLY 1:winman/activatesurface: ERROR
-{
-  "jtype":"afb-reply",
-  "request":{
-    "status":"failed",
-    "info":"Surface does not exist"
-  }
-}
-------
-
-=== redraw_fixer
-This utility is intended to be ran alongside the compositor, it will
-listen for certain events regarding surfaces, and issue a couple of
-other commands, to hopefully trigger a redraw of the surface in the
-compositor.
-
-It will print messages for each acted-upon event, and exit when the
-compositor exits.
-
-== Implementation Notes
-The window manager is implemented as a app-framework-binder binding. That
-means, the build produces one shared object that exports a binding
-interface.
-
-=== Binding code generation
-The binding API is rather simple; functions receive a json object
-describing arguments and return a json object describing the result or
-an error. In order to simplify development, the
-`generate-binding-glue.py` script was added, that contains a description
-of the API as a python dictionary. This script generates the header
-`afb_binding_api.hpp` and the afb binding functions as
-`afb_binding_glue.inl`. Where the latter is included in `main.cpp`.
-
-Each function for the AFB binding that is generated does the following:
-
-* Lock the binding mutex, so that we serialize all access to the
-  binding.
-* Do some debug logging (if wanted).
-* Check the binding state, i.e. the compositor might have exited
-  unexpectedly at which point it would not make sense to continue.
-* Extract the arguments from the json object that is provided (doing
-  some primitive type checking).
-* Call the afb_binding_api method corresponding to this binding function
-* Check the afb_binding_api's function return value, log an error state
-  and return the result to the afb request.
-
-The generated functions do also check for any "loose" exception that
-comes out of the afb_binding_api call (which in turn might call the
-actual non-trivial implementation in `App`). However, *IF* an exception
-is thrown and not handled inside the afb_binding_call, that internal
-state of the window manager might be broken at this time (hence the
-talkative error log).
-
-=== Structure
-The implementation is loosely split across the following source files:
-
-* `main.cpp`: The program entry point as used by the afb-daemon. This
-  file defines the afbBindingV2 symbol tat is used by the afb-daemon in
-  order to load a binding. It also defines the wayland fd event
-  dispatcher and some globals to be used (as context for the afb calls
-  we receive).
-* `afb_binding_api.cpp`: The implementation of the afb binding
-  functions. The actual functions are generated by
-  `generate-binding-glue.py` which generates a *.inl* file that is
-  included by `main.cpp`.
-* `app.cpp` / `app.hpp`: This is the main application logic
-  implementation.
-* `config.cpp` / `config.hpp`: Very simple configuration item interface.
-* `controller_hooks.hpp`: hook functions called by the wayland
-  controller to call into the App instance. Only a very limited number
-  of events are passed to the Application, which allowed the usage of
-  such a simple interface.
-* `json_helper.cpp` / `json_helper.hpp`: Smaller json related helper
-  functions.
-* `layers.cpp` / `layers.hpp`: Actually hold all the data from
-  layers.json configuration, do some transformations and service the App
-  implementation.
-* `layout.cpp` / `layout.hpp`: Very simple layout state for the
-  implementation of split layouts and tracking of the surfaces involved.
-* `policy.hpp`: PolicyManager implementation stub. Gets passed the
-  current and new layout on layout switch and can decide upon it being
-  valid or not.
-* `result.hpp`: Simple result class around `std::experimental::optional`
-  that additionally can hold a `char const *` to describe the error.
-* `util.cpp` / `util.hpp`: general utility functions and structs - and
-  preprocessor definitions (e.g. `log*()` to AFB logging functions.
-* `wayland.cpp` / `wayland.hpp`: A C++ object-oriented libwayland-client
-  wrapper. It is instanced in `main.cpp` and handles all our wayland
-  needs.
-
-// vim:set ft=asciidoc tw=72 spell spelllang=en_US:
-- 
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