Building a Kernel for Dream - G1 Android Development

Does anyone know how to make a new kernel/boot.img for Dream without running through the whole make process? The release-1.0 branch doesn't build, and cupcake is too.
I've managed to rebuild the kernel, but can't figure out what is packaged up to make the boot.img.

Koush said:
Does anyone know how to make a new kernel/boot.img for Dream without running through the whole make process? The release-1.0 branch doesn't build, and cupcake is too.
I've managed to rebuild the kernel, but can't figure out what is packaged up to make the boot.img.
Click to expand...
Click to collapse
Try the build environments I released with v1.3

Awesome, thanks! Should have scrolled to the end of the post for more goodies...

Koush said:
Does anyone know how to make a new kernel/boot.img for Dream without running through the whole make process? The release-1.0 branch doesn't build, and cupcake is too.
I've managed to rebuild the kernel, but can't figure out what is packaged up to make the boot.img.
Click to expand...
Click to collapse
Maybe i'm mistaken but doesn't the mkbootimg tool perform this task? It's documented in alansj's sticky here, section titled "Unpacking, Editing, and Repacking the Images"

Here's what I've done in the past. This assumes you have already repo sync'ed and have a toolchain available. I also work with a fresh copy of the MSM kernel from git. You can use the repo you checked out with repo (which is in .repo), but I can't remember how to do it off the top of my head right now. I make some assumptions people are comfortable with a "standard" kernel compile and git. These steps also assume you're on a Unix-based OS (Linux, Mac OS X, and (possibily) Cygwin).
1) In your clone of the MSM kernel repo, switch to the commit that Google used for their RC30 kernel:
git checkout -b my-build c092738
This creates a branch named "my-build" from the commit ID that starts with c092738e. I got this from the vendor/htc/dream git log. There are more recent kernels, but this one seems to be OK. You also want to make sure you dont use 2.6.27 yet. Apparently some of the kernel bits moved around, and the non-cupcake userspace doesn't know about this...but I never confirmed that.
2) Extract a starting config.
Unzip an RC30 full update from somewhere, and extract the kernel from boot.img. (I use split_bootimg.pl from the android-dls wiki). Remember where boot.img-kernel is located. Go into the directory containing the kernel tree you checked out in step 1, and run:
scripts/extract-ikconfig > g1.config
You can read the resulting config (less g1.config), but to use/change it:
mv g1.config .config
make ARCH=arm CROSS_COMPILE=/path/to/android/repo/prebuilt/linux-x86/toolchain/arm-eabi-4.2.1/bin/arm-eabi- oldconfig
make ARCH=arm CROSS_COMPILE=/path/to/android/repo/prebuilt/linux-x86/toolchain/arm-eabi-4.2.1/bin/arm-eabi- oldconfig
(Yes, run oldconfig twice!)
3) Apply patches. Apply any patches you want. JF's build sandbox has some good ones. I'd recommend the alarm driver fix at the very least (the uptime_fix.patch).
4) Edit your config. After patching, patches can give new config options. So the config needs to be updated. This is best done by:
make ARCH=arm CROSS_COMPILE=/path/to/android/repo/prebuilt/linux-x86/toolchain/arm-eabi-4.2.1/bin/arm-eabi- oldconfig
make ARCH=arm CROSS_COMPILE=/path/to/android/repo/prebuilt/linux-x86/toolchain/arm-eabi-4.2.1/bin/arm-eabi- oldconfig
make ARCH=arm CROSS_COMPILE=/path/to/android/repo/prebuilt/linux-x86/toolchain/arm-eabi-4.2.1/bin/arm-eabi- menuconfig
If a new option is added, oldconfig will stop and wait for some input. Also, running oldconfig twice is a paranoid way to make sure any dependencies within the kernel config process are ironed out.
With menuconfig, you can change the config as you desire. Remember to TURN OFF "Automatically append version information to the version string", else your kernel version string will be horked. Make sure it is turned off (no * by the option)! Also, do not turn off PREEMPT or set SMP in the config. Doing so will cause the wlan module to not load at runtime(unless you can compile your own module...which can be done, but I haven't done it yet). (Actually, be careful setting options, you may cause symbols to not be exported and prebuilt modules may not work afterwards...)
5) Build the kernel. After making your changes to the config, save them off and type:
make ARCH=arm CROSS_COMPILE=/path/to/android/repo/prebuilt/linux-x86/toolchain/arm-eabi-4.2.1/bin/arm-eabi- EXTRAVERSION=-018430-gfea26b0 zImage
make ARCH=arm CROSS_COMPILE=/path/to/android/repo/prebuilt/linux-x86/toolchain/arm-eabi-4.2.1/bin/arm-eabi- EXTRAVERSION=-018430-gfea26b0 modules
make ARCH=arm CROSS_COMPILE=/path/to/android/repo/prebuilt/linux-x86/toolchain/arm-eabi-4.2.1/bin/arm-eabi- INSTALL_MOD_PATH=/tmp/modules modules_install
The kernel to use lives in arch/arm/boot/zImage. (note the case!)
6) Follow the instructions at http://android-dls.com/wiki/index.p...cking.2C_Editing.2C_and_Re-Packing_the_images Remember, in the JF releases, the extra modules are put into a cramfs. What I've done:
rm /tmp/modules/lib/modules/2.6.25-018430-gfea26b0 source
rm /tmp/modules/lib/modules/2.6.25-018430-gfea26b0 build
mkcramfs -b 8192 /tmp/modules/lib/modules modules.cramfs
You can also fastboot install the kernel image.

Related

[GUIDE] Kernel Build Guide

This is a basic kernel build guide, to help those that keep coming into IRC asking for help.
If you follow this, you should have a working kernel that will work with ext4 or RFS.
NOTE::I wrote this at 1am, when Im kinda falling asleep, so there might be errors. Please let me know, and Ill fix it up
What you need:
A Linux system, with about 2gb free (This is written for 32bit systems, 64bit will need a compatible toolchain)
Development libraries
The kernel source
An ARM toolchain
An initramfs from an existing kernel
Downloads
EB13 source - search for D700 under mobile phone
Code Sourcery 2009q3 ARM toolchain
Daemon's Ext4/RFS Initramfs
Steps:
Set up the build environment
The first thing you need to do is set up the build environment.
For Ubuntu or other Debian-based system, you need the build-essential package and libncurses.
You can install this by running this command:
Code:
sudo apt-get install build-essential libncurses5-dev
If your not running Ubuntu/Debian, the packages are gcc, g++, libc-dev, and make.
Next, your going to need a directory for all your kernel build. You can't have spaces in any folder name. Im going to use /home/tortel/build/ for the rest of this guide.
Now you need to extract the kernel source to your directory. In the Samsung source file, its SPH-D700_kernel.tar
Next, extract the ARM toolchain into your build directory.
Last, extract your initramfs into the directory.
After this, your build directory should contain 4 things:
Code:
arm-2009q3/
eb13init/
Kernel/
build.sh
For this guide, Im not going to use the build.sh. If you want to, you'll need to configure that yourself.
Configure your kernel
Now the fun begins.
You need to edit the Kernel/Makefile file, and change line 184 to match where your toolchain is. My line 184:
Code:
CROSS_COMPILE ?= /home/tortel/build/arm2009q3/bin/arm-none-linux-gnueabi-
Now you need to configure the kernel.
The kernel configuration file is called .config, which is hidden by default (Ctrl+H shows hidden files in GNOME). You need to set lines 81-91, so it uses your initramfs. My lines:
Code:
CONFIG_BLK_DEV_INITRD=y
CONFIG_INITRAMFS_SOURCE="/home/tortel/kernel/eb13init/"
CONFIG_INITRAMFS_ROOT_UID=0
CONFIG_INITRAMFS_ROOT_GID=0
CONFIG_RD_GZIP=y
CONFIG_RD_BZIP2=y
CONFIG_RD_LZMA=y
# CONFIG_INITRAMFS_COMPRESSION_NONE is not set
CONFIG_INITRAMFS_COMPRESSION_GZIP=y
# CONFIG_INITRAMFS_COMPRESSION_BZIP2 is not set
# CONFIG_INITRAMFS_COMPRESSION_LZMA is not set
This will build your initramfs into the kernel image.
Now, your set to build.
Build the kernel
This is the easy part. Open a terminal, cd to build/Kernel and run make.
The commands:
Code:
cd build/Kernel/
make
If you have more than one core, you should add -j {1+ # of CPU cores} to make so it finishes faster. It only takes about 5min on my 2ghz C2D laptop.
Make it flashable!
Congrats, its built!
The file you want is Kernel/arch/arm/boot/zImage in your kernel source directory. After make finishes, run:
Code:
cp arch/arm/boot/zImage ..
This copies your kernel image file into your main build directory. Now, you need to put it into a flashable zip. To make it easy, here. Just throw the zImage into the root of that zip, put it on your SD card, and flash it.
Might want later
Advanced config stuff to come
Might want this too
Thank you for this, I'm glad too see this and others who have contributed great guides like this.
sent from "The Other Woman"
I was one of those people who kept bothering lol. I learned how to compile a kernal in two day though, now im on my way making a OC/UV Voodoo color kernal (coming soon) :]
Thanks alot
globalninja said:
I was one of those people who kept bothering lol. I learned how to compile a kernal in two day though, now im on my way making a OC/UV Voodoo color kernal (coming soon) :]
Thanks alot
Click to expand...
Click to collapse
what should I look into for making the changes necessary for an overclocking kernel?
Thanks for this helpful thread, and I had a question previously, that someone pm'ed me for. OP, please remove this reply if you feel inclined to. I had a question about the initramfs because my computer was having problems loading the page for the link.
Hey guys, kindof a noob to this.
How can I get an initramfs for DI18? Ideally, I could just use the one in the stock ROM unmodified, but I have no idea how to obtain it.
I figured it out! Used the scripts here to extract it from zImage:
http://forum.xda-developers.com/showthread.php?t=901152

[Q] kernel compilation steps for starters

Hi guys,
I'd like to tinker around a bit with the tiamat or other kernels for the Xoom
are the following steps enough to get it working ?
- clone the repo
- adjust toolchain paths (or create an external script that does it)
- make stingray_defconfig
- make -j2
- test-boot the zImage via fastboot
- if it's successful copy over the kernel-modules & flash the kernel via fastboot
how about an initramfs ?
have I forgotten anything ?
Many thanks in advance for your help !
edit:
slowly understanding how all this works,
still might need some help
I think that will get you started. I'm not an expert, but when I'm tinkering with kernels I pull the proc config strait from the device after flashing the kernel I want to modify. That way I know that the default config is correct. For example, if I wanted to modify the kernel running on an EOS nightly, after cloning the repo I would flash the EOS nightly ROM containing the kernel I want to modify. Then run the following commands to pull the kernel config from the kernel running on my device:
Code:
adb pull /proc/config.gz .
gunzip config.gz
mv config .config
The .config then goes in the root of the kernel source directory. That may do exactly the same thing as the "make defconfig" you mentioned but I just prefer to trust the defaults from the ROM and not the repo.

[GUIDE] How to compile Sidekick 4G Kernel [Ubuntu]

1) download source code from https://opensource.samsung.com/index.jsp. You are looking for source code for SGH-T839.
2) Get initramfs (Need to make a kernel package)
Extract it using extract boot http://www.mediafire.com/?lc12eceeh617b97.
This is why I am looking for a boot.img
extract it
Code:
tar -xvf extractboot.tar.gz
now move into directory with extract boot and copy your boot.img into here and do
Code:
./extractboot boot.img
3) Get mkboot tools
http://www.mediafire.com/?w06d1m6n1dgo4op
untar it by doing
Code:
tar -xvf $FILENAMEHERE
Add the bin directory to your path by moving to the bin directory and copying down the path then
Now you will add this to your path by editing your .bashrc file.
Go to your bashrc file
Code:
gedit ~/.bashrc
and adding this
Code:
PATH=$PATH:/FULLDIRECTORYYOUWROTEDOWN/
export PATH
4) Download the ARM toolchain
https://sourcery.mentor.com/sgpp/lite/arm/portal/package5385/public/arm-none-linux-gnueabi/arm-2009q3-67-arm-none-linux-gnueabi.bin
and
https://sourcery.mentor.com/sgpp/lite/arm/portal/package5355/public/arm-none-eabi/arm-2009q3-68-arm-none-eabi.bin
5) Install the ARM Toolchain
create the directory /opt/toolchains/arm-2009q3/
Code:
sudo mkdir /opt/toolchains/arm-2009q3/
then install the toolchain using /opt/toolchains/arm-2009q3/
as the install directory
Code:
sudo chmod +x arm-2009q3-68-arm-none-eabi.bin
sudo chmod +x arm-2009q3-67-arm-none-linux-gnueabi.bin
sudo ./arm-2009q3-67-arm-none-linux-gnueabi.bin -i console
sudo ./arm-2009q3-68-arm-none-eabi.bin -i console
6) Compile
Extract your source code and go to the directory Kernel and do the following
WARNING: MAKE SURE THERE ARE NO SPACES IN YOUR FILEPATH BECAUSE THE MAKEFILE DOESNT LIKE THEM.
Code:
make clean
make arch=arm sidekick_rev02_defconfig
make ARCH=arm HOSTCFLAGS="-g -O3" -j8 CROSS_COMPILE=/opt/toolchain/bin/arm-none-eabi-
Now copy any of the resulting compiled ko files into the initramfs file you have extracted and you should have what you need to package a kernel.
you forget initramfs
windxixi said:
you forget initramfs
Click to expand...
Click to collapse
yeah I kept it out so that somebody would post a boot.img then could do steps related to that. I am looking for a boot.img to get initramfs from
unpack zImage
Sent from my SGH-T839 using XDA
---------- Post added at 08:46 AM ---------- Previous post was at 07:49 AM ----------
and how to pack a boot.img?
A request to anyone building SK4G kernels.
Please disable the keystroke logging printk statements in the file:
Code:
drivers/input/keyboard/s3c-keypad.c
The lines look like this:
Code:
//printk("\nkey Pressed : key %d map %d\n",i, pdata->keycodes[i]);
and
Code:
//printk("\nkey Released : %d map %d\n",i,pdata->keycodes[i]);
It is possible to recover the actual keystrokes from the numerical codes those statements log, and the messages go into the dmesg buffer. So it's pretty easy to extract them and determine exactly what the user typed.
In the latest Samsung sources I've seen, those lines were already commented out. It makes sense to enable them while debugging a new ROM build, but please do disable them prior to building a kernel intended for general consumption.
Do you guys know if the available source code will produce a kernel that will work with kj2? the kernel version in SGH-T839_Opensource_Update1 looks to match up, but I compilied a zImage and it didn't boot on stock kj2. but I could very well be missing something.
I have done a small amount of kernel work on an HTC device, but I basically just used the Rom Kitchen to pack up my zImages with a boot.img-ramdisk to create a boot.img. I guess I might need a little more instruction for packing up a Samsung kernel. Is it also an option to just tar up the zImage and flash it with Odin/Heindall?
Thanks for this thread, and for any other advice!
Sent from my SGH-T839 using Tapatalk 2
In case it might be useful to someone else working on building a kernel.
The official and Bali_SK4G sources both seem to insist on building with debug symbols enabled for some of the modules. In particular, i was ending up with dhd.ko being 2.4 MB in size, where it should have been less than 400 KB.
The ideal case would be to determine why the debug symbols are being included -- commenting out the labelled debug options in the bcm4329 Makefile didn't accomplish this.
But a workaround is to strip the modules after the build is finished, before assembling the initramfs.
Has anyone been able to build a working zImage for KJ2 using Dr. Honk's Bali sources [1] and sduvick's KJ2 ramdisk files [2]?
I have been able to build a zImage of a reasonable size (6520 KB). But when I flash this to the KERNEL partition using heimdall, the device boot loops to the B&W Sidekick logo. It doesn't get far enough to show any adb log output.
I can then use the same heimdall flashing procedure to flash the Platypus Egg v1 zImage, or other KJ2-compatible zImage files, and the device boots and works properly.
So I'm trying to figure out what I'm doing wrong in building my zImage. If anyone has any advice I would be appreciative.
[1] https://github.com/drhonk/Bali_SK4G
[2] https://github.com/sduvick/SK4g_KJ2_Ramdisk
I got an updated Bali_SK4G kernel booting using the ramdisk from GenericGinger 2.0.
I have worked up some patches to disable the logging of keystrokes and other more trivial debug spew in dmesg. Also included is a Makefile patch that was required for the compile to complete with my toolchain.
https://carbon.flatlan.net/nxd/patches_Bali_SK4G_nxd.tar.bz2
md5sum: 5d14ac32de155cdca0fd82f14bc4ceca
These patches are GPL licensed, in compliance with the license for the Linux kernel itself. I make no guarantees about their suitability for any purpose. I grant permission to use them to anyone who would like to do so, so long as they comply with the GPL.
I'd like to make a compiled kernel available with these changes, but XDA's rules can be interpreted to mean that I must obtain permission from a series of upstream contributors, some of whom may not be reachable. Perhaps a moderator will clarify the parameters of the permission rule.

[GUIDE] How to Build and Package a Kernel [D2]

This thread aims to be a comprehensive guide to building and packaging kernels for US Variant Samsung Galaxy SIIIs
In my opinion, a kernel is a great way to get into building things for your device and its pretty easy to do too.
Intro
What is a kernel?
http://en.wikipedia.org/wiki/Kernel_(computing)
This guide is for US SGSIII's (d2att,d2cri,d2mtr,d2spr,d2tmo,d2usc,d2vzw,others?)
It may be possible to adapt this to other devices, but I am not responsible for anything that happens should you try to do this.
This guide assumes you have a general knowledge of the Linux operating system. If you've never used it, you might consider playing around
with it for awhile before attempting this guide.
Click to expand...
Click to collapse
Prerequisites
On all devices you must be rooted, on Verizon SGS3 (d2vzw) you must also have the unlocked (VRALE6) bootloader installed.
This is not the thread for figuring out how to do this. You can use the forum's search function to figure out how to do this on your device.
You'll need a computer or a virtual machine running ubuntu. You may be able to figure out how to get this working on other distributions,
but since ubuntu is generally the most accepted distribution to use for building android things, I'll stick to using that here.
At the time of this writing, I'm using ubuntu 12.10, 64-bit.
You'll need to install some packages on your ubuntu machine:
Code:
sudo apt-get install build-essential git zip unzip
On 64-bit you'll also need some multilib and 32-bit compatibility packages:
Code:
sudo apt-get install gcc-multilib g++-multilib lib32z1-dev
Click to expand...
Click to collapse
Setting up the Build Environment
Next, you'll need a toolchain which is used to actually build the kernel. You may download one of these:
GCC 4.4.3: Download || Mirror
GCC 4.6: Download || Mirror
GCC 4.7: Download || Mirror
If you aren't sure, go for 4.4.3 or 4.6.
4.7 requires some code changes to work. The original kernel developer may or may not have made these changes.
Here is what I needed to do in order for 4.7 to build, boot and have wifi work:
https://github.com/invisiblek/linux-msm-d2/commit/f8d7199d37cfbfa1bcb6b4bcae3fc15ae71fbdea
https://github.com/invisiblek/linux-msm-d2/commit/ea58076501e5874db7b934c215c4dae81ddfd0a6
The toolchains are also available in the android NDK.
*** There are many toolchains out there, some of you may know of the Linaro toolchain which is aimed to optimize your binary even further ***
*** If you choose to use a different toolchain, that is fine. Keep in mind that you may run into issues depending on the toolchain you use ***
You can check what your currently running kernel was built with by issuing these commands:
Code:
adb root
adb shell cat /proc/version
It should return something like:
Linux version 3.4.0-cyanogenmod-gc4f332c-00230-g93fb4aa-dirty ([email protected]) (gcc version 4.7 (GCC) ) #134 SMP PREEMPT Thu Feb 28 00:22:41 CST 2013
Click to expand...
Click to collapse
This shows my particular kernel here was built with GCC 4.7
You can use wget to download one of the links from above, in this instance we'll download version 4.4.3 from the first link:
Code:
wget http://invisiblek.org/arm-eabi-4.4.3.tar.bz2
Extract this to somewhere you will remember, probably your home directory.
Code:
mkdir arm-eabi-4.4.3
tar -xf arm-eabi-4.4.3.tar.bz2 -C arm-eabi-4.4.3/
Click to expand...
Click to collapse
Obtaining Source
Find someone's source to use as a base. This can be a source archive from Samsung, a kernel tree from CyanogenMod, or any other developer around that makes kernels for your device.
TIMEOUT
This is a good spot to stop and take note that the Linux kernel is licensed under the GNU General Public License (GPL): http://www.gnu.org/licenses/gpl-2.0.html
What does this mean you ask? It means that if you plan to share your kernel with the community (if it's good, please do so!) then you MUST share your
source code as well. I am not liable for what you choose to do once you start building kernels, but know this: if you share your kernel and do not
provide source code for it, you will get warnings from XDA for a determined amount of time, after that you may have your threads closed, deleted and
possibly your user account terminated. This is extremely important!
Also, you may run into more problems than just XDA. There are organizations out there that do take action if you consistently refuse to comply with the GPL.
I recommend you read this: http://www.gnu.org/licenses/gpl-2.0.html so that you are familiar with what legalities you are getting yourself into.
The main thing to remember is to share your source code if you decide to share your built kernel.
Click to expand...
Click to collapse
In this instance, we will use CyanogenMod's kernel source for the US Galaxy S3's. You may browse the source code here:
https://github.com/CyanogenMod/android_kernel_samsung_d2
You'll notice that the branch there is cm-10.1
This is the default branch of this repository on github. This means that if you intend to build this branch, you'll need to use it on CM version 10.1. Most
likely it will not function on another version.
To obtain the source code:
Code:
git clone https://github.com/CyanogenMod/android_kernel_samsung_d2
This will take a little while, be patient.
When done, you'll have a directory called android_kernel_samsung_d2, cd into this directory.
Code:
cd android_kernel_samsung_d2
Next, you'll need to set up a couple environment variables. These tell the system two things:
1. What CPU architecture to build for, in this case arm
2. Where to find the toolchain we downloaded earlier, so that the system can cross compile for arm
Code:
export ARCH=arm
export CROSS_COMPILE=~/arm-eabi-4.4.3/bin/arm-eabi-
You'll need to set these variables on each new session. You can modify your Makefile in the root of your kernel tree in order to have these set permanently.
Click to expand...
Click to collapse
Building
At this point you can make any changes to the source code that you want. If this is your first time, I recommend not making any changes and make sure you have a
sane build environment before adding any complications.
When you build a kernel, you need to choose a defconfig. This is a specialized configuration file, specifically tailored for your device.
CyanogenMod names their defconfigs for their devices like so: cyanogen_<device>_defconfig and they are located in arch/arm/configs/
Code:
ls arch/arm/configs/cyanogen*
In this example, we will build for d2vzw.
Set up your tree to build for the d2vzw:
Code:
make cyanogen_d2vzw_defconfig
(do this in your kernel's root directory, in this example it was android_kernel_samsung_d2/ )
Now you are ready to build:
First, determine how many cpu's your computer has. You'll use this number to determine how many jobs the compiler command will use. The more jobs you can use, the more
cpu threads the compile will take advantage of, thus you'll get faster builds. If you don't know, just assume you'll use the number 2. We'll use 2 as an example here.
Code:
make -j2
Where 2 is the number of CPU cores your build system has.
And now we wait...until it's done compiling...
You'll know it successfully compiled when you have this line when it stops:
Kernel: arch/arm/boot/zImage is ready
Click to expand...
Click to collapse
PROTIP:
If it stops somewhere other than "zImage is ready" then you had build errors. Try running the 'make' command with no options after it. This will run the compile on a single thread
and will cause it to stop compiling as soon as it hits an error. When you run it on multiple threads, it definitely goes much faster, but if an error occurs, the console doesn't stop
until it finishes all of its threads. Causing you to have to scroll up and search around for an error
Click to expand...
Click to collapse
Now, assuming the build completed successfully, you have two things you are concerned with: A zImage (the kernel binary itself) and your kernel modules, which get built based
on what was configured in your defconfig.
You'll find your zImage at: arch/arm/boot/zImage
Code:
ls arch/arm/boot/zImage
The modules are scattered all over the place, depending on where the source existed that they were compiled from. We can easily search for them using this command:
Code:
find . -name "*.ko"
If both of the previous commands completed, you are now ready to package your kernel up for testing.
Move up a directory before continuing.
Code:
cd ..
Click to expand...
Click to collapse
Packaging
You may know of an awesome developer by the name of koush.
Well, once upon a time, koush created a rather simple zip, called AnyKernel, that would flash a kernel on a device, regardless of what ramdisk the kernel has on it.
I've taken his zip and modified it for d2 devices and to work with the newer recoveries out there.
This has a script in it that will dump your current boot.img (kernel+ramdisk), unpack it, replace the kernel, repack it and flash it.
It'll also copy any modules to the proper directory (/system/lib/modules) and set permissions appropriately.
You can get a zip here: Download || Mirror
(You can get it here as well: https://github.com/invisiblek/AnyKernel )
(Everyone is invited to use this zip, it'll probably make your life easier to not have to worry about the ramdisk. Enjoy!)
IMPORTANT
This AnyKernel package is for US variations of the Galaxy S3.
NOT the international (I9300) or any other device.
There are checks in the updater-script that will ensure you are running a d2 device before it does anything.
If you were to remove these checks, and not modify the partition that it flashes to later, you could end up with a brick.
If you intend to adapt this package for another device (please, do this! its a very handy script!), make sure you know it well, or ask someone to help you determine your device's
partition scheme before using it.
The risk here is due to the fact that the script doesn't know your device's partition scheme. It is configured specifically for the d2 devices. Flashing it on something else, who's boot
partition is somewhere else, might cause a bad flash to the bootloader partition (bad bad news if this happens).
Just be careful if you want to use this on another device. You won't run into problems if you use this on a d2 device.
EDIT: I made modifications that should make this less likely, but please, if you intend to use this on a different device (which is completely fine!) make sure you configure
the scripts to flash to the proper partitions.
Click to expand...
Click to collapse
Download and extract one of the above, we'll again use the first link for this example:
Code:
wget http://invisiblek.org/AnyKernel_samsung-d2.zip
unzip AnyKernel_samsung-d2.zip -d AnyKernel/
Now we'll copy our newly compiled zImage (still referring to the same kernel directory we used above, your repo might be called something different)
Code:
cp android_kernel_samsung_d2/arch/arm/boot/zImage AnyKernel/kernel/
cp `find android_kernel_samsung_d2 -name "*.ko"` AnyKernel/modules/
Finally we are ready to zip this up and test out flashing it.
Code:
cd AnyKernel
zip ../MyAwesomeKernel.zip -r *
cd ..
You'll now have a file named MyAwesomeKernel.zip which you should be able to flash via custom recovery (TWRP or CWM)
Click to expand...
Click to collapse
Extra Credit/Protips
Learn to use git. It's very powerful and great way to store your code.
Learn to use adb. It's an invaluable tool for any android developer.
Touchwiz and AOSP-based kernels are different. This means you cannot take CyanogenMod's source, build a kernel and expect it to work on a Touchwiz-based ROM.
Build a ROM next: http://wiki.cyanogenmod.org/w/Build_for_d2vzw
Crackflash your own stuff!
ALWAYS NANDROID!
Click to expand...
Click to collapse
Source code for all of my projects can be found here: http://github.com/invisiblek
FAQ
Q: How do I update my source tree to the latest that is available from where I downloaded it?
A: This can be handy if, for instance, you are building a CyanogenMod kernel and they added some patches, after you downloaded the source, that you want to include in your next build. You'll want to cd to your kernel tree and issue a git pull:
Code:
cd android_kernel_samsung_d2
git pull
You may then continue with the building instructions.
This may, however, have other problems if you've made changes to files. You might run into conflicts. I won't cover fixing any of this here, its not in the scope of this thread.
Q: I'm using X as a kernel base, but Y has a patch that I really like. How do I get it in my kernel easily?
A: I'll let you check Google for this answer, but I'll give you a hint use: git cherry-pick
Nice tutorial bro! Always good to learn something new everyday
Really is a good thread,thanks
This guide would have made things too easy for me.
Too easy, indeed. haha
Great job, invisiblek! AnyKernel is the beez neez.
Ok so this is a noob question but I gotta ask anyway lol. Ok so I cloned the kernel source, I made my edits, now how do I push all this to my github?
I already have a github account, I already made a new repo for the kernel. Here's a link to my github if you need it...
https://github.com/ghicks12/d2vzw_kernel.git
spc_hicks09 said:
Ok so this is a noob question but I gotta ask anyway lol. Ok so I cloned the kernel source, I made my edits, now how do I push all this to my github?
I already have a github account, I already made a new repo for the kernel. Here's a link to my github if you need it...
https://github.com/ghicks12/d2vzw_kernel.git
Click to expand...
Click to collapse
git remote add origin git_location_you_created_on_github.git
git push -u origin somebranch
The -u is for first time run only, you can just git push afterwards.
Sent from my SCH-I535
GideonX said:
git remote add origin git_location_you_created_on_github.git
git push -u origin somebranch
The -u is for first time run only, you can just git push afterwards.
Sent from my SCH-I535
Click to expand...
Click to collapse
Thanks! When I run
Code:
git remote add origin https://github.com/ghicks12/d2vzw_kernel.git
I get this back:
Code:
fatal: remote origin already exists.
I'm editing a CM based kernel, not sure if that matters or not?
That just means you added the remote already. Just issue the push command then.
Sent from my SCH-I535
Why is this happening? I don't know what i did wrong
[email protected]:~/cm$ make VARIANT_DEFCONFIG=cyanogen_d2att_defconfig
scripts/kconfig/conf --silentoldconfig Kconfig
drivers/media/video/msm/Kconfig:123:warning: choice value used outside its choice group
drivers/media/video/msm/Kconfig:128:warning: choice value used outside its choice group
***
*** Configuration file ".config" not found!
***
*** Please run some configurator (e.g. "make oldconfig" or
*** "make menuconfig" or "make xconfig").
***
make[2]: *** [silentoldconfig] Error 1
make[1]: *** [silentoldconfig] Error 2
make: *** No rule to make target `include/config/auto.conf', needed by `include/config/kernel.release'. Stop.
[email protected]:~/cm$
Hey. I'm having some problems with some GIT terminology and procedures. I'm a .NET developer and I use TFS and SVN on a daily basis. Forgive me if this is complete off basis from what you'd do with GIT.
What I want to do is merge one branch into another branch. In other words I want to take the latest kernel source from my favorite dev and merge in the latest from cyanogen's 4.3 d2 branch. Is this a rebase thing? It doesn't seem like cherrypicking to me.
I have successfully compiled kernel and made modules.I inserted zImage and modules inside any kernel updater,flashed via TWRP.When reboot stuck in odin and it says could not do normal boot.

[Guide] Building post 2017 android kernel from source

About this guide
I have been building kernels for many machine types and have been fiddling around with custom android kernels for my own phone but to my great frustration the rules changed quite a lot for my new phone. It seems every kernel after 2017 is A LOT harder to build and needs quite some fiddling around te get it to boot. The documentation is terrible the least on the steps and all howtos are all outdated by now. This guide shares with you the secrets to build yourself a modern post 2017 kernel from source. I only own a op7 at this moment but I am pretty sure the rules apply to all devices.
So why do we need to build our own kernel? Well that's simple. I have scrolled through many custom kernels missing a simple module that I need. In my case binfmt. Perhaps you need a specific device driver compiled into your kernel or you want to hack in/patch in some special functions that are only needed by you. Or you love a certain kernel but need that one little adjustment in the configs that this kernel doesn’t have and so on.
Lets get through it step by step but I do assume you know something about Linux, you know how to use the terminal and that you have some knowledge on building binaries from source. Ready? Ok lets get started.
These steps are required to be followed to be successful:
1. Set up a building environment
2. Obtain the kernel source
3. Download the proper tool-chain
4. Adjust configuration files to match your needs
5. Build the actual kernel image
6. Backup your current boot.img!!!
7. Trow the image into a anykernel zip and flash it.
8. Close your eyes prey and run the kernel.
Prerequisites
You will need:
A fairly fast computer with lets say 4 gigs of RAM and a decent CPU.
A workable linux distribution that you can boot into (I prefer ubuntu bionic at this moment).
The kernel sources for your device.
ROOT!!
Lots of spare time.
A attitude that makes you unstoppable.
1. Setting up the building environment
Ok lets first open a terminal. You will need the terminal a lot. As a matter of fact it will be your friend through this guide so better get used to it. Assuming you are on a ubuntu like distribution lets fetch the important packages first
Code:
$sudo apt install build-essential bizon flex git
This command will install some of the prerequisites you need to do anything. More packages will need to be installed on the way but at least you will be able to type $make
Now lets create a working directory. Go into your home folder and create a working directory which will later on contain your kernel sources and tool chain.
Code:
$cd
$mkdir [COLOR="MediumTurquoise"]name-of-your-working-folder[/COLOR]
2. Obtain the kernel source
This one is tricky as my experience have learned me the kernel sources supplied by my own vendor are usually badly documented and contain a few bugs here and there resulting in either build errors or a unbootable kernel. So usually I grab a custom kernel that has minimal changes to the stock kernel and boots by only using a single kernel file without extra kernel modules attached. The custom kernels usually have the nasty building bugs flawed out and thus your chances for success are higher. I used the exkernel in my case and out of respect for the hard work of flang2 I bought the app that came along.
To get the sources google around and find the sources on for example git and click the download or clone button there and copy the link of the depository.
Then simply clone the depository to your working directory so after changing to your working directory type
Code:
$git clone link-you-just-copied
Git will now automatically clone the entire kernel source into the source sub-directory. You can change the name of this directory to make you life easier.
3. Download the proper tool-chain
This is where I lost many days and weeks of my life. Where do we find the proper tool-chain for our kernel?
You basically need 3 compilers
clang
GCC
device-tree-compiler
There are many versions of clang and GCC and you will need to find the one that matches your kernel and builds for your cpu architecture. I will assume in this guide that your CPU is aarch64 or arm64 (both names are used at the same time).
To obtain clang head over to the following address:
"https://android.googlesource.com/platform/prebuilts/clang/host/linux-x86/"
now in the tags and branches you can find the version of android you are looking for. If your kernel is for android 9 then use the android 9 tag. Click on it and then click tgz which will provide you with a huge tarball.
Create a folder in your working directory named toolchain en extract the contents of the tarball into the sub-folder clang.
You can try any subversion of clang there is but I recommend to simply peek into the build.config files located in the root of your kernel source directory which usually specify the exact subversion of clang used.
Time to get GCC which is easier since there is only one version right now.
Head over to
"https://android.googlesource.com/platform/prebuilts/gcc/linux-x86/arm/arm-linux-androideabi-4.9/"
and use the correct version here as well. In my case I picked the latest build. Then do the same as for clang but name the sub-folder GCC or whatever you please to do.
And then finally get yourself the device-tree-compiler
Head over to
"https://github.com/dgibson/dtc/tree/v1.4.4"
and clone this depository into ~/your-working-directory/toolchain/
and navigate to the subdir you cloned it into
then build by typing
Code:
$make
any missing package errors will need you to install them using
Code:
$sudo apt install missing-package-name
and do make again until the build completes.
If all went well your tool-chain and working directory will look like this:
Code:
/[COLOR="mediumturquoise"]current-working-dir[/COLOR]/[COLOR="mediumturquoise"]kernel-source-dir[/COLOR]/
|
/toolchain/
|
/clang/
/gcc/
/dtc/
4. Adjust configuration files to match your needs
Lets first grab the correct defconfig file and setup the build directory. This defconfig file contains the default kernel configuration parameters which you propably want to adjust.
Head over to ~/working-directory/kernel-source-dir/arch/arm64/configs/
see what you can find there. I found the elementalX_defconfig file which is the file I needed to build the Exkernel from scratch. If you are trying a stock kernel dive a little bit deeper into the vendor folder and see if you can find a good config file there.
Alternatively sometimes the config is hidden on your device itself. Have a look at
/proc/config.gz
the file inside the archive contains a valid defconfig for your device but beware your may need to open it with menuconfig first and save it again to make it workable for the compiler script.
Place the defconfig file you like to use into the configs folder.
(Skip the following step if your are going to build your kernel for the first time because we first want to see it work.)
Now head over to your kernel source dir and type the following command
Code:
$PATH="~/[COLOR="mediumturquoise"]working-dir[/COLOR]/toolchain/clang/[COLOR="mediumturquoise"]clang-r353983c[/COLOR]/bin:~/[COLOR="mediumturquoise"]working-dir[/COLOR]/toolchain/gcc/a[COLOR="mediumturquoise"]arch64-linux-android-4.9[/COLOR]/bin:${PATH}" \
make menuconfig O=out \
ARCH=arm64 \
CC=clang \
CLANG_TRIPLE=aarch64-linux-gnu- \
CROSS_COMPILE=aarch64-linux-android-
now remember to use the correct paths to your tool-chain. In this command I use clang-r353983c but you may use a different version. The same applies for linux-android-4.9.
I would like to thank Nathan Chance for supplying documentation on the clang tool-chain on his github.
If all well you will be presented with a menu in which you can adjust things. First open the defconfig file you wish to use and then save the file after you are done. Now REMEMBER! With this command the menuconfig will save your new file into the /kernel-source-dir/out folder.
(end of the skipped step)
Now it is time to prepare our kernel build using the following command (do this from your kernel source dir) and remember that this command will look in the /kernel-source-dir/arch/arm64/configs/ directory
$make O=out ARCH=arm64 name-of-your-defconfig
If all goes well you will see something like configuration written to .config
Everything is up and ready to go. Your hart will start pounding from this moment on
5. Build the actual kernel image
This is where things get complicated. I hope you have many years to live because this part consumes time, a lot of it.
type
Code:
$PATH="~/[COLOR="mediumturquoise"]working-dir[/COLOR]/toolchain/clang/[COLOR="mediumturquoise"]clang-r353983c[/COLOR]/bin:~/[COLOR="mediumturquoise"]working-dir[/COLOR]/toolchain/gcc/[COLOR="mediumturquoise"]aarch64-linux-android-4.9[/COLOR]/bin:${PATH}" \
make -j$(nproc --all) O=out \
ARCH=arm64 \
CC=clang \
DTC=~/[COLOR="mediumturquoise"]working-directory[/COLOR]/toolchain/dtc/dtc \
CLANG_TRIPLE=aarch64-linux-gnu- \
CROSS_COMPILE=aarch64-linux-android-
ready set GO!
This will depending on your machine take between forever and eternally. You will witness many warnings on the DTC build seems normal these days and a few warnings on the CC part. Most important is that no errors are thrown at you.
If all goes well you will see a normal exit status and you will have a “working” kernel image.
“Error?: Well that happens. Try a different build of clang check your command line. And if all that fails try to find out what is wrong in the source and that means digging through thousands of forum pages until you find out whats wrong. But using the google tools usually goes well.”
Almost there go and check
kernel-source-dir/out/arch/arm64/boot
and there should be a image-dtb or image.gz-dtb file depending on you settings.
That is your kernel image right there. The difference in size between image and image-dtb should not be huge. 10Megs in difference usually means your dtb is not good but trying is the only way to find out if it works.
6. Backup your current boot.img!!!
You know what to do here right? Do not skip this step unless you like bricked devices or want to reflash and lose your data and all that kind of stuff. Not sure what you are doing stop here or backup your entire device including system vendor etc.
7. Trow the image into a anykernel zip and flash it.
Ok something changed in the last few years. Unpacking repacking and booting using fastboot somehow gives me problems. Dm-verity errors and all kind of red screens. Signing the boot image results into new errors. Well this is how I did it.
Get yourself a anykernel zip file. I used the Exkernel.zip because it only contains a kernel image which I like. Open the zip in a good zip tool (I used ark) and replace the image-dtb file with the one you created. Place this new zip you created on a memory stick and then….
Flash it using twrp or any tool of choice.
8. Close your eyes prey and run the kernel.
Two things can happen.
1. Blank screen nothing happens. Only god can help you, repeat all the steps.
2. Your android starts booting. Start crying of joy
Check in your android if this is indeed the kernel you build. If so time to make some adjustments to your configs or happily enjoy your boosted phone.
Now please remember. If you plan to distribute your kernel that you do the correct steps of accrediting the original programmer and trow the source online. If you use a already custom kernel please respect the hard work of the maker and communicate your plans with him/her.

Categories

Resources