DeprecatedPortingToAndroid10 » History » Revision 281
Porting Replicant to Android 10¶
- Table of contents
- Porting Replicant to Android 10
- Building Replicant 10
- Cleanups to be done
- Upstreaming status
- Modem status
- Other attempts
- Known error messages that are safe to ignore
Active development has moved towards LineageOS 17 (based on Android 10).
The basic features working on Replicant 9 have been confirmed to work on Replicant 10, but not everything has been tested yet on either version. Replicant 9 source code and build instruction have been kept to do regression tracking: Porting Replicant to Android 9.
Building Replicant 10¶
$ repo init -u https://git.replicant.us/replicant-next/manifest.git -b replicant-10-dev $ repo sync
Alternatively a shallow copy of the source tree can be fetched in order to save on disk space:
$ repo init -u https://git.replicant.us/replicant-next/manifest.git -b replicant-10-dev --depth=1 $ repo sync -c
To unshallow a specific module:
$ cd path/to/module $ git fetch --unshallow <remote>
For Trisquel 8¶
sudo apt-get install bc bison build-essential bsdmainutils ccache curl flex g++-multilib gcc-multilib gettext git gnupg gperf imagemagick lib32ncurses5-dev lib32readline-dev lib32z1-dev liblz4-tool libncurses5-dev libsdl1.2-dev libssl-dev libwxgtk3.0-dev libxml2 libxml2-utils lzop python-mako pngcrush rsync schedtool squashfs-tools xsltproc zip zlib1g-dev sudo apt-get install gcc-5-arm-linux-gnueabi
Fixing the build environment¶
Allow system binaries for building¶
By default, the Android 10 build system can only use the prebuilt binaries it ships. However, in Replicant's path to freedom, we would like to use the system binaries instead. Setting the following envrionment variable allows that:
$ export TEMPORARY_DISABLE_PATH_RESTRICTIONS=true
Note that setting this variable does not automatically make the build system use the system binaries, it just allows it. Prebuilts are still being used now. Lots of further effort must be put into transitioning to the system binaries.
Mako (Python) for Mesa¶
To avoid the following error:
16:20:13 See https://android.googlesource.com/platform/build/+/master/Changes.md#PATH_Tools for more information. [ 3% 2585/70375] build out/target/product/i9305/gen/STATIC_LIBRARIES/libmesa_nir_intermediates/nir/nir_builder_opcodes.h FAILED: out/target/product/i9305/gen/STATIC_LIBRARIES/libmesa_nir_intermediates/nir/nir_builder_opcodes.h /bin/bash -c "python external/mesa3d/src/compiler/nir/nir_builder_opcodes_h.py external/mesa3d/src/compiler/nir/nir_opcodes.py > out/target/product/i9305/gen/STATIC_LIBRARIES/libmesa_nir_intermediates/nir/nir_builder_opcodes.h" Traceback (most recent call last): File "external/mesa3d/src/compiler/nir/nir_builder_opcodes_h.py", line 106, in <module> from mako.template import Template ImportError: No module named mako.template 16:20:20 ninja failed with: exit status 1
You need to run the following command:
$ cd prebuilts/build-tools/path/linux-x86/ $ rm python && ln -s /usr/bin/python python
Java heap space¶
The Java heap size is automatically set according to the available system memory. On machines with 8 GB or less RAM, it is set to a value which is too low, and will result in the following error during the build:
Exception in thread "main" java.lang.OutOfMemoryError: Java heap space
The heap size can be increased with an envirnoment variable:
$ export _JAVA_OPTIONS="-Xmx3g"
Reduce parallel jobs to avoid killed processes¶
Increasing the Java heap space is not enough to get a successful build on machines with 8 GB or less RAM. It is also necessary to reduce the number of parallel jobs, to avoid processes from being killed due to lack of memory. This typically happens during the build of
For greater speed, you may let your build run with the defaults, wait for it to fail due to killed processes, and then relunch the build with:
$ make -j1
By default, Ninja, the underlaying build system for Android, used when you run
make bacon, computes the number of parallel jobs according to the number of CPUs on your machine (typically #CPUs + 2 parallel jobs).
Launching the build¶
$ source build/envsetup.sh $ lunch lineage_i9305-eng $ make
Install the images¶
$ cd out/target/product/i9305 $ sudo heimdall flash --BOOT boot.img --USERDATA userdata.img --SYSTEM system.img
As the device IDs are the ones given by the Linux kernel, they are not in the adb udev rules, so for now it requires to run adb as root:
$ sudo adb shell * daemon not running; starting now at tcp:5037 * daemon started successfully i9305:/ # $ sudo adb kill-server $ adb shell * daemon not running; starting now at tcp:5037 * daemon started successfully error: no devices/emulators found
So make sure to kill the adb-server and run it as root:
$ adb kill-server $ sudo adb shell * daemon not running; starting now at tcp:5037 * daemon started successfully i9305:/ #
You can also follow the boot progress with adb:
adb logcat adb logcat -b main
Note that the device can go into suspend at any time, so adb might be interrupted. That looks like that:
First you get a shell
$ sudo adb shell i9305:/ #
Then the connection is interrupted:
$ adb shell i9305:/ # [randomdev@fullyfreelaptop ]$
The effect with adb logcat is similar.
Getting the latest changes¶
- The repositories are being constantly modified with
git push --forceas we are trying things out, and don't want to make the commits history look too dirty, so be sure to backup your local changes.
- Sometimes the manifest repository is also modified with
git push --force. In that case the following commands will loose all the work you did locally but will make the repository consistent with upstream repositories again:
$ rm -rf .repo/manifests .repo/manifests.git .repo/manifest.xml $ repo init -u https://git.replicant.us/replicant-next/manifest.git -b replicant-10-dev $ repo sync --force-sync
- The following command might also be necessary to make the state consistent with upstream repositories again, when the manifest history wasn't rewritten, but it will also loose all the work you did locally:
$ repo sync --force-sync
If you use Parabola, you may be interested in running Trisquel 8 in LXC.
To do that first debootstrap a Trisquel 8 rootfs.
Parabola's debootstrap does support Trisquel 8 and its manual has an example on how to do that:
$ man debootstrap [...] # debootstrap flidas flidas-root http://archive.trisquel.info/trisquel
Then you can use virt-manager to setup the LXC instance.The advantages of this solution are that:
- The LXC guest and host shares their resources (CPU, RAM) with almost no penalty
- Trisquel 8 is not a rolling release distribution
- you need to configure the Trisquel 8 LXC instance (vimrc, sshd_config, etc)
- It's more complicated to setup
- The Android build system outputs a warning message about not being able to use namespaces which may become mandatory in newer Android versions
Cleanups to be done¶
- Make adb work as user by using the right USB IDs, and make userspace do the USB setup.
Make the kernel not use hardcoded CMDLINE_FORCENot possible unless the bootloader is changed or Linux is very heavily patched.
- Make the kernel not use hardcoded partitions if possible (though we use system as root)
- Make a clean Gatekeeper HAL module implementation instead of using the same hack than goldfish
- Look at init.rc documentation to see if init.rc can be overriden clearly with the override statement to see if it's possible to keep the serial console patch for -eng
- The stock bootloader is incompatible with Linux, see BootloadersIncompatibleWithLinux for more information. So we maintain patches to enable the Galaxy SIII, and Galaxy Note II to boot with the stock bootloader. In the long run we need to look into using u-boot in the kernel partition as using u-boot instead of the stock bootloader currently require nonfree and non-redistributable software (BL1).
- For the patches that are not merged yet, see the issues of the redmine upstreaming sub-project
- Fully tested under GNU/Linux only
- Can initialize completely the modem and receive messages (see the #1954 bug report for the logs)
- Needs more cleanup but there is now a better abstraction
- Ported to Replicant 9 using a wrapper for the API >=12 in libsamsung-ril source code that needs to be removed
- Tested under Replicant 9 without up to date libsamsung-ipc (no modem init)
- Tested and validated under Replicant 6 (doesn't break telephony)
Modem status TODO¶
- Implement the missing part to shut down the modem, close the interfaces and such, in order to need to reboot after each test.
- Continue to clean up the libsamsung-ipc and libsamsung-ril patches, test the patches in Replicant 6 when applicable, and merge them in the upstream repositories.
- Convert the firmware loading driver to the upstream API and then adapt libsamsung-ipc for that. This should also benefit other devices like the Galaxy SIII 4G, and the Galaxy Note II 4G which probably don't need much more to get their modem supported by upstream Linux.
- Cleanup and convert the rest of the drivers to look like the ones for the Nokia N900 and adapt the userspace in libsamsung-ipc, and merge libsamsung-ipc support for that once the kernel API is stable.
- Test the code under Replicant 9 when the graphics status will enable to have decent enough speed to do some testing through human interaction.
First month of full time equivalent work:
|Only boots with graphics, not much more
Builds under Trisquel8
* Boots with adb.
* Has ultra slow graphics
|find, remove and document proprietary software in LineageOS 16
|find, remove and document privacy issues in LineageOS 16
|Now in 5.3
|rebrand LineageOS as Replicant
|See the modem status for more details
|Total: 147h (~1 month)
| * port libsamsung-ril and libsamsung-ipc to Android 9
* Make the modem driver and libsamsung-ipc work together
|See the modem status for more details
Look which sensor libraries can be used
|Already done by the unofficial LineageOS port of the Galaxy SIII (i9300), needs testing
|add support for Audio with the upstream kernel driver
| Might be way faster, depending on what Android 9 uses
See also this bugreport
| * The source code on which the work was based changed from AOSP to an unofficial LineageOS port to a port of i9305 support for AOSP by Joonas to the official LineageOS so it's now supported by default
* The work to factorize the code between the i9300 and i9305 still need to be done
|create a recovery
|add internal WiFi support and validate the functionality
|add external WiFi dongles support
|External dongles support might be tricky
* The installation instructions are now generic enough.
* Some long standing TODO were also done along the way like adding backup instructions for the EFS.
* The current instructions are still for Replicant 6.0 and will need to be updated for Replicant 9.0
|Estimate the amount of work to Reduce the attack surface
|Estimate the amount of work to add in-system upgrades
1 The generic instructions were tested at Install parties in Paris
Easy, because it's similar enough to the Galaxy SIII (I9300)¶
|Galaxy Note II (N7100)
|port the EA8061 LCD Linux driver
|port the S6EVR02 LCD Linux driver
|port the MAX77693 flash led Linux driver
|android: add support for the Note II (N7100) and factorize the code with Galaxy SIII (i9300) and Galaxy SIII 4G (i9305)
|Should be similar to the Galaxy SIII
|port the sensors libraries and other device specific libraries
|It's difficult to evaluate how much time it could take
|add support for Audio with the upstream kernel driver
|Should be similar to the Galaxy SIII
|Galaxy Note 8.0 (N5100) and 8.0 WiFi (N5110)
|Evaluate the time required to do the port
Needs more work and unknown upstream Linux status¶
|Galaxy S II (i9100)
|Linux: devboard dts upstream? unknown status
|Galaxy Note (N7000)
|unknown Linux upstream status
|Galaxy Nexus (I9250)
|OMAP4, no dts upstream
|Galaxy Tab 2 7.0 (P3100), 7.0 WiFi (P3110), 10.1 (P5100), 10.1 WiFi (P5110)
|GTA04 >= A4
|TODO: a RIL needs to be written, userspace GPS support is missing, audio scenarios, etc
Replicant 6.0 changes¶
See the Samsung-ipc page.
- It might be interesting to contact the people doing ports once we have something working well enough.
- It is also interesting to look at other attempts to understand if a given device is powerful enough to run Android 9 and what configuration was used to achieve it.
|* March 3 2019 release
|* August 20 2019 release
| Issues: * Uses a Samsung kernel
* Uses too many nonfree libraries
=> Probably nothing we could reuse from its code
|* September 13 2019 release
Links for other attempts¶
CustomROMs i9300 components¶
|Loads the MAC Address of the WiFi network interface
|Might be useful
|Loads the wifi kernel module (like modprobe) and setup firmware filesystems permissions
|May be useful
|seems to contains ril related stuff as well
|Look if the ril stuff is required, go for standard audio
|livedisplay is a feature similar to what redshift does on GNU/Linux
|Not sure if it works with mainline
|seem meant for audio/video decoding offload
|assembly obtimized color conversion and resize code
|check assembly code license, not sure if useful
|all other directories in hardware/samsung/exynos/
|nonfree firmwares, nonfree software?, smdk kernel?
|audio/video decoding offload
|Avoid using that
|nonfree firmwares?, nonfree software?, smdk kernel?
|some light libraries, display stuff (gralloc, etc), 2D acceleration (FIMG), camera (FIMC), 3D acceleration, etc
|Avoid using that for now
Known error messages that are safe to ignore¶
- TestHarnessModeService: Failed to start Test Harness Mode; no implementation of PersistentDataBlockManagerInternal was bound
- JniUtils: Could not load native library jni_latinimegoogle
- Android build requirements - hardware and software
- Why LineageOS Developers are building Android Go-optimized custom ROMs
- Android Go recommended default values for propreties for optimization
- Team InFusion i9300 optimized system.prop
- Hack to fix high CPU usage caused by logd
- Use low-end video codecs
- Optimize ActivityManager cached apps
- Use 1Gb Dalvik config