Android applications using Python and SL4A, Part 1

Set up your development environment

Configure your Windows workstation to run Scripting Layer for Android


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This content is part of the series:Android applications using Python and SL4A, Part 1

Stay tuned for additional content in this series.

About this series

Part 1, this article, kicks off the series by showing you how to install everything necessary to get started writing Python scripts on your Android device. Part 2 will present useful scripting examples to get real work done. It will also explore some of the available Android API calls, including the various windows. Finally, the series will explore how to build a complete user interface just like you would in the Java language.

A common misconception about developing for the Google Android platform is that you have to write your code in the Java™ language. The truth is, you actually have a multitude of options through the Scripting Layer for Android (SL4A) project. SL4A started out as a 20% project by Google employee Damon Kohler. That was almost two years and four major versions ago.

SL4A provides a platform for several scripting languages, including Beanshell, Lua, Perl, Python, and Rhino. There's also support for basic shell scripting. Today, the Python portion of the SL4A project has developed into a project of its own, due in part to the popularity of Python and the desire to decouple the releases of new Python functionality from the main SL4A release cycle.

This article focuses on using Python to write applications for the Android platform. Python is a great tool for writing both simple scripts and complex, multi-threaded applications. The great thing about having Python on Android is the opportunity to use the untold thousands of lines of code already written and freely available. Python is an easy language to learn if you've never used it before, and you will find many resources available on the Internet to help get you up to speed.

Installation and setup

You must download and install several prerequisites before you can start developing with SL4A. The first is a full Java Development Kit (JDK). You can find the latest version on the Oracle Developer site.

Next you need the Android software development kit (SDK). Two download choices are available on the main Android developer site: a .zip file and an .exe file. When you download and run the .exe file, you'll be presented with a screen where you must choose which versions of the SDK and support files you want to install (see Figure 1).

Figure 1. Choose which Android SDK options you want to download
Window in which you choose your SDK options
Window in which you choose your SDK options

For this article, I installed and tested everything on a Windows® 7 64-bit machine.

Because this article is about developing applications for the Android platform using Python, you obviously need to install Python on your development machine. Windows does not come with Python installed. As of this writing, the SL4A Python version is 2.6.2. Download either the 32- or 64-bit version of Python 2.6 to stay compatible.

It's a good idea to add a few links to the Android SDK in your PATH statement to make it easier to launch the SDK Manager and other tools. To do this in Windows 7, perform these steps:

  1. Press the Windows key, and then click Search.
  2. In the text box, enter Environment.
  3. Click Edit the system environment variables.
  4. In the window that opens, click Environment Variables, then select the PATH variable in the User variables list.
  5. Click Edit, and then add the path to your Android SDK tools directory.

The string you need to add looks like this:


You must add the semicolon (;) before the new path to append a new directory. Once that's entered, click OK three times.

Installing SL4A on an Android device is similar to the process for any other Android application. You can scan the QR code on the main SL4A project site with your device to download the SL4A installation file. It should automatically launch when the download is finished. At this point, you should see an installation screen like the one in Figure 2.

Figure 2. SL4A installation screen
The installation screen for SL4A

Clicking Install starts the process.

The final step is to install the Python interpreter on your device. You can do so using any of several methods. From the emulator, you can enter sl4a download in the browser's search box (Figure 3).

Figure 3. The SL4A download screen
Image showing the SL4A download screen

Clicking the PythonForAndroid_r4.apk link starts the download. To actually launch the installer, view the notification screen by clicking and dragging from the top of the emulator screen toward the bottom of the screen. Clicking the Download complete message launches the Python for Android installer (Figure 4).

Figure 4. Python for Android initial installation screen
Image showing the initial SL4A installation screen

Clicking Install launches a process that downloads and unpacks several .zip files. For the purposes of this article, simply click Install on the primary installation screen (Figure 5).

Figure 5. Python for Android primary installation screen
Imaging showing the primary Python installation screen

You should see three separate progress windows. The first shows the download, and then the extraction of the files onto the SD card. If everything works, an "Installation Successful" message appears.

Android SDK basics

There are two basic methods for testing your Python code using SL4A: using an emulator or using an actual physical device. The Android SDK provides basic emulator capability and the tools to create an emulated device with the same characteristics as a physical device. In some cases, as with the Samsung tablet add-on, you have a preconfigured emulator available for your use.

The SDK Manager functions as both an update manager and a virtual device creation tool. Each time you launch SDK Manager, it connects to the Android developer site to check for new releases. (You can bypass this process by clicking Cancel.) At this point, you should see the Android SDK and AVD Manager window, shown in Figure 6.

Figure 6. Android SDK and AVD Manager
Image showing the Android SDK and AVD Manager screen
Image showing the Android SDK and AVD Manager screen

Selecting Virtual devices in the directory tree displays all previously defined Android virtual devices (AVDs) in the details pane. To create a new emulator device, click New. In the Create New Android Virtual Device (AVD) window, provide the required information in the Name, Target, and SD Card Size fields. Figure 7 shows the entries for my test device. The name must not contain spaces, and you should allow at least 100MB for storage. Choose the appropriate Android version number for your target device. This drop-down list displays only the available options previously downloaded.

Figure 7. The Create New AVD Wizard
The Create New Android Virtual Device (AVD) window
The Create New Android Virtual Device (AVD) window

Next, click Create AVD. A pop-up window provides the details of your new device. To launch any of the available emulator images, select the desired target, and then click Start. In the Launch Options window, you can proceed with defaults for screen size, or you can select the Scale display to real size check box and choose something larger. A value of 7 seems to work well (see Figure 8). To launch the emulator with a clean slate, select the Wipe user data check box.

Figure 8. AVD launch options
Image showing the AVD launch options

Another indispensable tool provided with the Android SDK is the Android Device Bridge (ADB). This tool provides such functions as installing applications (.apk files), copying files to or from a device, and issuing shell commands on the device. You also use ADB to actually launch SL4A on a device so that you can execute programs from your workstation. To establish communication between your host workstation and a device, you must use ADB to forward TCP/IP traffic from port 9999 to a specific port on the device. Open a Command window, and enter the following command line:

$ adb forward tcp:9999 tcp:42306

The second port number comes from the device. With the latest version of the SL4A, you can set this number in the preferences. For the standard release, you have to use the number SL4A gives you.

Now, launch SL4A, and then click Menu. From the six options at the bottom of the window, click View, then click Interpreters (Figure 9).

Figure 9. Launch a remote server from the SL4A Interpreters menu
Imaginge showing the Interpreters menu, from which you launch a remote server

Click Menu once more, then click Private to launch a private server.

For a real device, the difference is that Private starts the server using the USB port, and Public uses Wi-Fi. If you view the notifications page again, you'll see that the SL4A service is running (Figure 10).

Figure 10. Android notification screen
Image showing that the SL4A service is running
Image showing that the SL4A service is running

Click the message to see the actual port number assigned. In this case, you use port number 42306 for the second TCP value in the adb forward command. Now, you're ready to actually write some Python code and test it on the device.

Hello World in Python for Android

It's almost obligatory in any introductory programming article to write a "hello world" program. I do that here to demonstrate the number of ways you can write and test your Python code using SL4A. Here's what the code looks like:

import android
droid = android.Android()
result = droid.makeToast('Hello, world!')

Every SL4A scripting language uses an import file— for Python, in this case—to set up the interface between the script and the underlying Android application programming interfaces (APIs). You can enter this code directly on your device either in the interpreter (refer back to Figure 9) or by using the editor. To use the interpreter, from the Interpreters screen, launch the Python interpreter by selecting Python 2.6.2. On the resulting screen, you can enter the code above; after the last line, you should see a pop-up window with the words "Hello, world!"

Typing on either an emulated or real device can be tedious. Python's IDLE console and editor prove indispensable when combined with the ADB tool to write code on a PC and test it on an Android device. The only thing you'll need is a local copy of the file. You can either extract it from the file available on the SL4A downloads page or transfer it from the device using the adb pull command. It's also handy to have a directory named SDCARD at the root of your primary system drive to mirror what's on your emulated device. This makes things easier from a file path perspective whenever you run a script on the local machine that needs to access the file system. Figure 11 shows the Hello World script in the IDLE console.

Figure 11. Hello World in the Python IDLE console
Image showing the Hello World application in the Python IDLE console
Image showing the Hello World application in the Python IDLE console

If you launched the server and executed the adb forward command, you should see no error and the "Toast" message shown in Figure 12.

Figure 12. Hello World pop-up message
Image showing the Hello World pop-up message on the device

In Windows, you can launch an edit window in IDLE by clicking File > New Window. This window gives you a complete edit and test capability from your development machine to either an emulated or real Android device.

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Zone=Mobile development, Open source
ArticleTitle=Android applications using Python and SL4A, Part 1: Set up your development environment