This page will teach you:
- what screens and apps are in InfiniTime
- how to implement your own app
The user interface of InfiniTime is made up of screens.
Screens that are opened from the app launcher are considered apps.
Every app in InfiniTime is its own class.
An instance of the class is created when the app is launched, and destroyed when the user exits the app.
Apps run inside the DisplayApp
task (briefly discussed here).
Apps are responsible for everything drawn on the screen when they are running.
Apps can be refreshed periodically and reacts to external events (touch or button).
Every app class is declared inside the namespace Pinetime::Applications::Screens
and inherits
from Pinetime::Applications::Screens::Screen
.
Each app defines its own constructor.
The constructors mostly take references to InfiniTime Controllers
(ex: Alarm, DateTime, BLE services, Settings,...)
the app needs for its operations. The constructor is responsible for initializing the UI of the app.
The destructor cleans up LVGL and restores any changes (for example re-enable sleeping).
App classes can override bool OnButtonPushed()
, bool OnTouchEvent(TouchEvents event)
and bool OnTouchEvent(uint16_t x, uint16_t y)
to implement their own functionality for those events.
Apps that need to be refreshed periodically create an lv_task
(using lv_task_create()
)
that will call the method Refresh()
periodically.
There are basically 3 types of applications : system apps and user apps and watch faces.
System applications are always built into InfiniTime, and InfiniTime cannot work properly without those apps. Settings, notifications and the application launcher are examples of such system applications.
User applications are optionally built into the firmware. They extend the functionalities of the system.
Watch faces are very similar to the user apps, they are optional, but at least one must be built into the firmware.
The distinction between system apps, user apps and watch faces allows for more flexibility and customization. This allows to easily select which user applications and watch faces must be built into the firmware without overflowing the system memory.
Apps are created by DisplayApp
in DisplayApp::LoadScreen()
.
This method simply call the creates an instance of the class that corresponds to the app specified in parameters.
The constructor of system apps is called directly. If the application is a user app,
the corresponding AppDescription
is first retrieved from userApps
and then the function create
is called to create an instance of the app.
Watch faces are handled in a very similar way as the user apps : they are created by DisplayApp
in the method DisplayApp::LoadScreen()
when the application type is Apps::Clock
.
The list of user applications is generated at build time by the consteval
function CreateAppDescriptions()
in UserApps.h
. This method takes the list of applications that must be built into the firmware image.
This list of applications is defined as a list Apps
enum values named UserAppTypes
in Apps.h
.
For each application listed in UserAppTypes
, an entry of type AppDescription
is added to the array userApps
.
This entry is created by using the information provided by a template AppTraits
that is customized for every user application.
Here is an example of an AppTraits customized for the Alarm application. It defines the type of application, its icon and a function that returns an instance of the application.
template <>
struct AppTraits<Apps::Alarm> {
static constexpr Apps app = Apps::Alarm;
static constexpr const char* icon = Screens::Symbols::clock;
static Screens::Screen* Create(AppControllers& controllers) {
return new Screens::Alarm(controllers.alarmController,
controllers.settingsController.GetClockType(),
*controllers.systemTask,
controllers.motorController);
};
};
This array userApps
is used by DisplayApp
to create the applications and the AppLauncher
to list all available applications.
The list of available watch faces is also generated at build time by the consteval
function CreateWatchFaceDescriptions()
in UserApps.h
in the same way as the user apps.
Watch faces must declare a WatchFaceTraits
so that the corresponding WatchFaceDescription
can be generated.
Here is an example of WatchFaceTraits
:
template <>
struct WatchFaceTraits<WatchFace::Analog> {
static constexpr WatchFace watchFace = WatchFace::Analog;
static constexpr const char* name = "Analog face";
static Screens::Screen* Create(AppControllers& controllers) {
return new Screens::WatchFaceAnalog(controllers.dateTimeController,
controllers.batteryController,
controllers.bleController,
controllers.notificationManager,
controllers.settingsController);
};
static bool IsAvailable(Pinetime::Controllers::FS& /*filesystem*/) {
return true;
}
};
A minimal user app could look like this:
MyApp.h:
#pragma once
#include "displayapp/Apps.h"
#include "displayapp/screens/Screen.h"
#include "displayapp/Controllers.h"
#include "Symbols.h"
namespace Pinetime {
namespace Applications {
namespace Screens {
class MyApp : public Screen {
public:
MyApp();
~MyApp() override;
};
}
template <>
struct AppTraits<Apps::MyApp> {
static constexpr Apps app = Apps::MyApp;
static constexpr const char* icon = Screens::Symbols::myApp;
static Screens::Screen* Create(AppControllers& controllers) {
return new Screens::MyApp();
}
};
}
}
MyApp.cpp:
#include "displayapp/screens/MyApp.h"
using namespace Pinetime::Applications::Screens;
MyApp::MyApp() {
lv_obj_t* title = lv_label_create(lv_scr_act(), nullptr);
lv_label_set_text_static(title, "My test application");
lv_label_set_align(title, LV_LABEL_ALIGN_CENTER);
lv_obj_align(title, lv_scr_act(), LV_ALIGN_CENTER, 0, 0);
}
MyApp::~MyApp() {
lv_obj_clean(lv_scr_act());
}
Both of these files should be in displayapp/screens/.
Now we have our very own app, but InfiniTime does not know about it yet.
The first step is to include your MyApp.cpp
(or any new cpp files for that matter)
in the compilation by adding it to CMakeLists.txt.
The next step to making it launch-able is to give your app an id.
To do this, add an entry in the enum class Pinetime::Applications::Apps
(displayapp/apps/Apps.h).
Name this entry after your app. Add #include "displayapp/screens/MyApp.h"
to the file displayapp/DisplayApp.cpp.
If your application is a system application, go to the function DisplayApp::LoadScreen
and add another case to the switch statement.
The case will be the id you gave your app earlier.
If your app needs any additional arguments, this is the place to pass them.
If your application is a user application, you don't need to add anything in DisplayApp, everything will be automatically generated for you. The user application will also be automatically be added to the app launcher menu.
Since the list of user application is generated by CMake, you need to add the variable ENABLE_USERAPPS
to the command line of CMake.
This variable must be set with a string composed of an ordered list of the user applications that must be built into the firmware.
The items of the list are fields from the enumeration Apps
.
Ex : build the firmware with 3 user application : Alarm, Timer and MyApp (the application will be listed in this specific order in the application menu).
$ cmake ... -DENABLE_USERAPPS="Apps::Alarm, Apps::Timer, Apps::MyApp" ...
Similarly, the list of watch faces is also generated by CMake, so you need to add the variable ENABLE_WATCHFACES
to the command line of CMake.
It must be set with the comma separated list of watch faces that will be built into the firmware.
Ex: build the firmware with 3 watch faces : Analog, PineTimeStyle and Infineat:
$ cmake ... -DENABLE_WATCHFACES="WatchFace::Analog,WatchFace::PineTimeStyle,WatchFace::Infineat" ...
You should now be able to build the firmware and flash it to your PineTime. Yay!
Please remember to pay attention to the UI guidelines when designing an app that you want to be included in InfiniTime.