Android Notes

Here are some miscellaneous notes on Android. See Android on OMAP, too.

oom killer info
Google (Android) developer Arve Hjonevag added a lowmemorykiller feature to the staging area of the Linux kernel in January of 2009. This feature tries to reclaim memory before the system runs out (acting as a kind of cache manager, according to Arve). In Linus' 2.6.28-rc tree this appears in

Application lifecycle (and activity states) can be found here: http://code.google.com/android/intro/lifecycle.html

Applications in different stages of their lifecycle receive a different oom_adj value, which affects the probability of their being reaped.

Initial lowmemorykiller thresholds are set by /etc/init.rc (with the following lines):

setprop ro.FOREGROUND_APP_ADJ 0 setprop ro.VISIBLE_APP_ADJ 1 setprop ro.SECONDARY_SERVER_ADJ 2 setprop ro.HIDDEN_APP_MIN_ADJ 7 setprop ro.CONTENT_PROVIDER_ADJ 14 setprop ro.EMPTY_APP_ADJ 15 setprop ro.FOREGROUND_APP_MEM 1536 setprop ro.VISIBLE_APP_MEM 2048 setprop ro.SECONDARY_SERVER_MEM 4096 setprop ro.HIDDEN_APP_MEM 5120 setprop ro.CONTENT_PROVIDER_MEM 5632 setprop ro.EMPTY_APP_MEM 6144 write /sys/module/lowmemorykiller/parameters/adj 0,1,2,7,14,15 write /proc/sys/vm/overcommit_memory 1 write /sys/module/lowmemorykiller/parameters/minfree 1536,2048,4096,5120,5632,6144 class_start default # Set init its forked children's oom_adj. write /proc/1/oom_adj -16
 * 1) Define the oom_adj values for the classes of processes that can be
 * 2) killed by the kernel.  These are used in ActivityManagerService.
 * 1) Define the memory thresholds at which the above process classes will
 * 2) be killed.  These numbers are in pages (4k).
 * 1) Write value must be consistent with the above properties.

Routines to actually calculate the oom_adj value, based on application state are in the ActivityManager. See frameworks/base/services/java/com/android/server/am/ActivityManagerService.java:UpdateOomAdjLocked(...)

and frameworks/base/core/java/android/os/Process.java:setOomAdj => frameworks/base/core/jni/android_util_Process.cpp:android_os_Process_setOomAdj

init sequence
See this blog entry for an overview of the sequence of operations performed by the 'init' program: http://blog.csdn.net/loughsky/archive/2008/11/13/3293922.aspx

kernel power management
See http://mjg59.livejournal.com/100221.html for a discussion of kernel modifications to support power management.

(Also, the comments are interesting, in that they delve into (and speculate about) the possible history of certain components of the Android system.)

C Library (bionic) info
See the excellent article: http://codingrelic.geekhold.com/2008/11/six-million-dollar-libc.html for an overview of bionic.

From: http://discuz-android.blogspot.com/2008/10/google-android-native-libc-bionic.html

Google developed a custom library for the C compiler (libc) called Bionic. This was necessary for three main reasons:
 * License: they wanted to keep GPL out of user-space. Bionic code uses the BSD license.
 * Size: the library has to be loaded in each process, so it needs to be small. Bionic is about 200K, or half the size of glibc (the GNU version of libc).
 * Speed: limited CPU power means it needs to be fast. Bionic has a small size and fast code paths, including a very fast and small custom pthread implementation.

Bionic has built-in support for important Android-specific services such as system properties and logging. It doesn’t support certain POSIX features, like C++ exceptions and wide chars, which were not needed on Android. Thus it’s not quite compatible with the gnu libc. All native code must be compiled against bionic, not glibc.

threads
The bionic C library has it's own thread API, not the same as either original LinuxThreads or NPTL.

From: http://www.mail-archive.com/uclibc@uclibc.org/msg02787.html

android thread library (from bionic libc) is minimalist : - use most of the linux kernel thread features (futex, CLONE_THREAD) unlike old linuxpthread. - it doesn't support thread cancellation (see CAVEATS file) - it misses some pthread functions : for example no barrier, missing *timedwait variant, ... - very basic gdb support that only work through gdbserver - some theoric race

Busybox
Android ships with a utility suite (called 'toolbox') that is not busybox.

You can get a binary busybox for Android here The site includes instructions for easy installation on your device.

Bootchart
The 'init' program in Android has built-in capability to gather the data needed to produce a bootchart image. See README.BOOTCHART in the directory system/core/init directory of the Android source repository for details.

See Using Bootchart on Android

Benchmarks
Apparently, [droidbench is an integrated benchmark program for Android.

debugging tips
Quick stack dump - "kill -3 " will put a stack trace in the log file. (Use logcat to view)

Re-flashing a device
See How (not) to brick the Android Developer Phone, Feb. 2009, LWN.net

Android 101 by Haykuro - describes basic re-flashing of a G1 (so has some non-ADP1 information).

Tutorial on Android flash partitions
HOWTO: Unpack, Edit, and Repack Boot Images is a good tutorial on Android Flash partitions.

Nandroid (NAND flash backup tool)
Nandroid is a tool for backing up your flash partitions. It is highly recommended if you plan to experiment with customizations of your system software. It requires busybox (not in regular Android images).

Compiling native applications
Because Android uses it's own C library (not glibc), it is tricky to compile native applications for.

Here are some instructions for compiling "hello world" on the android phone: http://android-tricks.blogspot.com/2009/02/hello-world-c-program-on-using-android.html

Building
See Updating and rebuilding Android LWN.net, May 2009

Building the kernel from scratch
See http://honeypod.blogspot.com/2007/12/compile-android-kernel-from-source.html

Organizations

 * http://www.rethink-wireless.com/?article_id=1264 - Japan Consortium with 25 members - Open Embedded Software Foundation (OESF)- started in March to promote non-phone Android devices in Japan.