Difference between revisions of "Cross-compiling (ES series)"
m (→The Hello World kernel module(s)) |
m (→The Makefile) |
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Line 646: | Line 646: | ||
+ | === The HelloWorld-2 kernel module === | ||
+ | Now that we have gained some intellectual kernel meat, we can design a slightly more | ||
+ | useful kernel module. One that actually does something. | ||
− | '''WIP!!''' .... | + | The following code is an example kernel module that shows the life cycle and |
+ | provides a function to user space over ''debugfs''. It creates a new file in | ||
+ | '''''/sys/kernel/debug/hello/ping''''' that can be opened and read from user space. | ||
+ | Reading this file gives a short message that includes the number of times the | ||
+ | file has been opened. All original comments have been removed, but can be | ||
+ | found in [3]. | ||
+ | |||
+ | |||
+ | hellok2.c: | ||
+ | #include <linux/init.h> | ||
+ | #include <linux/module.h> | ||
+ | #include <linux/debugfs.h> | ||
+ | #include <linux/seq_file.h> | ||
+ | MODULE_LICENSE("Dual BSD/GPL"); | ||
+ | |||
+ | static struct dentry *root_dir; | ||
+ | static int calls; | ||
+ | static int hello_print(struct seq_file *s, void *p) { | ||
+ | seq_printf(s, "Called %d times\n", ++calls); | ||
+ | return 0; | ||
+ | } | ||
+ | |||
+ | static int hello_open(struct inode *inode, struct file *file) { | ||
+ | return single_open(file, hello_print, inode->i_private); | ||
+ | } | ||
+ | |||
+ | static const struct file_operations hello_fops = { | ||
+ | .open = hello_open, | ||
+ | .write = NULL, | ||
+ | .read = seq_read, | ||
+ | .llseek = seq_lseek, | ||
+ | .owner = THIS_MODULE, | ||
+ | }; | ||
+ | |||
+ | static int hello_init(void) { | ||
+ | printk(KERN_ALERT "Hello world\n"); | ||
+ | root_dir = debugfs_create_dir("hello", NULL); | ||
+ | debugfs_create_file("ping", 0444, root_dir, NULL, &hello_fops); | ||
+ | return 0; | ||
+ | } | ||
+ | |||
+ | static void hello_exit(void) { | ||
+ | debugfs_remove_recursive(root_dir); | ||
+ | printk(KERN_ALERT "Goodbye Dear Module\n"); | ||
+ | } | ||
+ | |||
+ | module_init(hello_init); | ||
+ | module_exit(hello_exit); | ||
+ | |||
+ | The Makefile for this is your homework, but a good hint is that the tricky part | ||
+ | this time, is not the Makefile, but enabling DEBUGFS in your kernel, if not already | ||
+ | enabled... | ||
+ | |||
+ | |||
+ | |||
+ | |||
+ | |||
+ | |||
+ | <span style="color:red"> '''WIP!!''' ....</span> | ||
=== References === | === References === |
Revision as of 02:58, 7 January 2013
This is Work In Progress !!
No answers/solutions can be expected here yet. If you need quick answers Google the forums.
@developers:
Do not change or update this page without first checking/asking on the "Talk" page or
support forum thread for latest status/info.
Contents
Cross Compiling
This is an introduction to cross-compiling for MST10P (MStar/MediaTek) based TV sets. It is primary intended as a crash course for getting even a novice to be able to quickly compile his/her own programs to run on their TV sets. As such, we will assume that you are using a Windows based PC with a basic installation of Cygwin. The modification for using a Linux based PC will then be minimal and even simpler.
Introduction
If you have never cross-compiled anything before, this is the right place for you. If you already have experience and knowledge with cross compilation, this wiki may still be helpful to get you started. If you are looking for information on how to build your own cross-compiler, this place is not for you. (Look HERE instead.)
What this Wiki will cover and not.
- We will use a popular pre-compiled cross-compiler.
- We will work on a Windows (Intel/AMD) based PC.
- All examples herein are based on a UExxES5700 TV set, and should be reproducable on the same.
- We will not cover the compilation of a cross-compiler!
- We will not cover other cross-compilers, operating systems or processor architectures.
A few Questions and Answers:
Q: What is a cross-compiler? A: Basically it is just a compiler built to run on one type of processor (e.g. Intel x86), but which is built and configured for compiling code for another processor (e.g. ARM). Q: Should I get a pre-compiled cross-compiler or compile my own? A: We hate to waste our time compiling compilers, so always try to find a pre-compiled one! Q: Where can I find help to configure my cross-compiler? A: Not here. If it's not already in here or in our forums, we don't know. Q: Do I need to install the TV specific platform sources? (Such as UExxES6xxx.zip ?) A: ** It depends on what you need to compile. (See below.) Q: Do I have to install the Samsung platform ARM toolchain? (Such as VDLinux-ARMv7-4.4-202-toolchain-v2r2-20110630.tgz ?) A: ** Hopefully not, but it depends on what you need to compile. (See below.)
** = unknown and not fact!
Things you need to get started.
WIP! This need checking and adjustment...
1. Install Cygwin for Windows. (Not necessary, but very helpful for the various *nix tools and file utilities.) 2. Install a good text editor (EditPlus, Notepad++ etc.) 3. Download a suitable pre-compiled cross-compiler. 4. Download your TV kernel sources. 5. Download your TV firmware sources. (?) 6.
Steps:
(A) Install & Verify the pre-compiled cross-compiler on your PC. (B) Verify your TV sets processor / architecture. (C) Compile "HelloWorld" and run it on TV. (D) Installing the Samsung Kernel Sources. (E) Setting up your development environment. - Setting up your PATH's + other shell/system variables) - Setting up your Makefile - other? (F) Compiling a Kernel Module (G) Compiling the Kernel
Extras:
(D)Installing the Samsung cross-compiler.(E) Installing your TV Kernel sources. (F) Installing your TV firmware sources. (G) Compiling the Kernel (H) Compiling a Kernel module
...
(A) Installing the Cross-Compiler
Go to the Mentor Graphics website, and download the "Sourcery CodeBench Lite Edition" from HERE.
(You'll need to supply an email to get a download link.)
There you will get a few different choices based on the platform. You will have choices such as:
arm-2012.09-63-arm-none-eabi.exe arm-2012.09-63-arm-none-eabi-i686-mingw32.tar.bz2 arm-2012.09-64-arm-none-linux-gnueabi.exe arm-2012.09-64-arm-none-linux-gnueabi-i686-mingw32.tar.bz2 arm-2012.09-64-arm-none-linux-gnueabi-i686-pc-linux-gnu.tar.bz2
If you use a x86 Windows based system, choose: "arm-2012.09-64-arm-none-linux-gnueabi.exe".
Run it, and when asked, change the installation directory to something simple like: C:\zarm\csbench
The rest of the installation procedure is self explanatory.
After installation, verify that the cross-compiler PATH variable is properly set and working:
$ arm-none-linux-gnueabi-gcc --version arm-none-linux-gnueabi-gcc.exe (Sourcery CodeBench Lite 2012.09-64) 4.7.2 Copyright (C) 2012 Free Software Foundation, Inc. This is free software; see the source for copying conditions. There is NO warranty; not even for MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
Since this is a Windows installer, Cygwin may or may not catch the updated system PATH variable. Open a new Cygwin shell and check:
$ echo $PATH
If it's not working, you'll have to add the following line in your ~/.bash_profile file.
(On some systems this file is called ".profile".)
PATH=${PATH}:/cygdrive/path/to/csbench/bin;
This should do it.
******************************************************************************* If you want to have access to the cross-compiler's man pages you'll have to add the following line to /etc/man.conf: MANPATH_MAP /path/to/csbench/bin /path/to/csbench/share/doc/arm-arm-none-linux-gnueabi/man and/or possibly this line to your ~/.bashrc MANPATH=${MANPATH}:/path/to/csbench/share/doc/arm-arm-none-linux-gnueabi/man; *******************************************************************************
If you have more questions, check out the Sourcery ARM FAQ.
(B) Determine the TV processor & architecture
In order to properly compile and run anything, you need to know what processor you're programming for. Here is how to find that information.
1. Root your TV and login to a shell. (Instructions HERE.)
2. Verify your TV's processor type and architecture by executing the following at the shell prompt.
shell> cat /proc/cpuinfo Processor : ARMv7 Processor rev 0 (v7l) processor : 0 BogoMIPS : 1794.04 processor : 1 BogoMIPS : 1794.04 Features : swp half thumb fastmult vfp edsp neon vfpv3 CPU implementer : 0x41 CPU architecture: 7 CPU variant : 0x3 CPU part : 0xc09 CPU revision : 0 Hardware : amber3 Revision : 0000 Serial : 0000000000000000
Now, this is not obvious in any way. Problem is that an "ARM" processor is really
only a license to manufacture a processor according to ARM Holding's specifications.
Therefore any hardware manufacturer can have a processor with an ARM "core". In
addition, and to make it even more confusing, an ARM "core" belong to an ARM
"architecture" which belong to an ARM "family", whose numbers are little related...
The only way to get some insight is looking at the WikiPedia entries:
1. "List of ARM microprocessor cores"
2. "ARM architecture"
and compare what you find there with the interpretation of the ARM "Features" above, where:
----------------------------------------------------------------------------- Feature Description ----------------------------------------------------------------------------- swp SWP (SWaP) instruction, which is used to implement a binary semaphore (mutex) half Half-precision (16-bit) floating point, "__fp16" data type in gcc thumb Thumb instructions fastmult Fast multiplication vfp Vector Floating Point instruction extension edsp Enhanced DSP instructions neon NEON SIMD instructions vfpv3 Vector Floating Point instruction extension Version 3 -----------------------------------------------------------------------------
So from the above we think we have a dual core processor of the ARMv7-R or
ARMv7-A architecture. (Of either the Coretx-R or A families, respectively.)
But the only NEON enabled processors with both DSP and VFPV3, are the
Cortex-A8 and "Cortex-A9 MPCore". But this is not good enough...for a perfectionist.
So we search in the ARM on-line documentation for
"Main ID Register":
Main ID Register bit functions:
----------------------------------------------------------------------------- Bits Field Value Function ----------------------------------------------------------------------------- [31:24] Implementor 0x41 implementor: ARM [23:20] Variant 0x3 variant number or major revision of the processor [19:16] Architecture 0x7 architecture is given in the feature registers [15:4] Primary part number 0xC09 part number: Cortex-A9 [3:0] Revision 0x0 revision number or minor revision of the processor -----------------------------------------------------------------------------
Here is a brief list of ARM primary part numbers.
ARM core CPU part ------------------------ ARM920 0x920 ARM926 0x926 ARM946 0x946 ARM966 0x966 ARM1136 0xb36 ARM1156 0xb56 ARM1176 0xb76 ARM11 MPCore 0xb02 Cortex A5 0xc05 Cortex A8 0xc08 Cortex A9 0xc09 Cortex A15 0xc0f Cortex R4 0xc14 Cortex R5 0xc15 ------------------------
We finally conclude that our TV processor contains a dual core Cortex-A9 MPCore from the ARMv7-A architecture.
Done!
(C) Compiling "HelloWorld"
We would like to compile our "Hello World" program for our TV.
So create a file like this:
hellow.c
#include <stdio.h> int main(void) { printf("Hello world\n"); return (0); }
We now, need to determine what compiler flags to use with our cross-compiler. There are several dozens of compiler options for the CodeSourcery compiler, but we are only interested in the following.
Here are the most important CodeSorcery ARM Cross Compiler options:
-march= Specify the name of the target architecture -mcpu= Specify the name of the target CPU -mfpu= Specify the name of the target FPU hardware/format -marm Generate code in 32 bit ARM state. -mthumb Generate code for Thumb state -mlittle-endian Assume target CPU is configured as little endian -mthumb-interwork Support calls between Thumb and ARM instruction -mglibc Use GNU C library -muclibc Use uClibc C library -static Compile and include all static libraries
Here are the choices for the above options:
Known ARM ABIs (for use with the -mabi= option): aapcs aapcs-linux apcs-gnu atpcs iwmmxt Known ARM architectures (for use with the -march= option): armv2 armv2a armv3 armv3m armv4 armv4t armv5 armv5e armv5t armv5te armv6 armv6-m armv6j armv6k armv6s-m armv6t2 armv6z armv6zk armv7 armv7-a armv7-m armv7-r armv7e-m ep9312 iwmmxt iwmmxt2 native Known ARM CPUs (for use with the -mcpu= and -mtune= options): arm1020e arm1020t arm1022e arm1026ej-s arm10e arm10tdmi arm1136j-s arm1136jf-s arm1156t2-s arm1156t2f-s arm1176jz-s arm1176jzf-s arm2 arm250 arm3 arm6 arm60 arm600 arm610 arm620 arm7 arm70 arm700 arm700i arm710 arm7100 arm710c arm710t arm720 arm720t arm740t arm7500 arm7500fe arm7d arm7di arm7dm arm7dmi arm7m arm7tdmi arm7tdmi-s arm8 arm810 arm9 arm920 arm920t arm922t arm926ej-s arm940t arm946e-s arm966e-s arm968e-s arm9e arm9tdmi cortex-a15 cortex-a5 cortex-a7 cortex-a8 cortex-a9 cortex-m0 cortex-m1 cortex-m3 cortex-m4 cortex-r4 cortex-r4f cortex-r5 ep9312 fa526 fa606te fa626 fa626te fa726te fmp626 generic-armv7-a iwmmxt iwmmxt2 mpcore mpcorenovfp native strongarm strongarm110 strongarm1100 strongarm1110 xscale Known ARM FPUs (for use with the -mfpu= option): fpa fpe2 fpe3 fpv4-sp-d16 maverick neon neon-fp16 neon-vfpv4 vfp vfp3 vfpv3 vfpv3-d16 vfpv3-d16-fp16 vfpv3-fp16 vfpv3xd vfpv3xd-fp16 vfpv4 vfpv4-d16
ARMed with our previous knowledge from part (B) we can try the following:
$ arm-none-linux-gnueabi-gcc.exe -march=armv7-a -mcpu=cortex-a9 -marm -mlittle-endian -mglibc -static hellow.c -o hellows $ arm-none-linux-gnueabi-gcc.exe -march=armv7-a -mcpu=cortex-a9 -marm -mlittle-endian -mglibc hellow.c -o hellowd
Great! It seem to work. But as you can see, a statically compiled binary is about 100x bigger than a dynamically compiled one of size ~10K. But sometimes we need a static binary as it can help overcome crippled, buggy or platform specific system libraries.
But let's check if we got what we expected:
$ file hellows hellows: ELF 32-bit LSB executable, ARM, version 1 (SYSV), statically linked, for GNU/Linux 2.6.16, not stripped $ file hellowd hellowd: ELF 32-bit LSB executable, ARM, version 1 (SYSV), dynamically linked (uses shared libs), for GNU/Linux 2.6.16, not stripped $ arm-none-linux-gnueabi-objdump.exe -x hellows |less ...
Looks good, let's try to run it. ( /dtv/usb/sda1 )
ftp <tv_ip> ftp> put hellows /tmp/bin/hellows ftp> put hellowd /tmp/bin/hellowd ftp> quit nc <tv_ip> 23 shell> chmod 777 /tmp/bin/hellow* shell> hellows Hello world shell> hellowd Hello world
Excellent! We are now ready to try a more advanced example where we will make use of some platform specific system libraries to make a kernel module.
(D) Installing the Samsung Kernel Sources
Download the sources relevant to your TV set from the Samsung Open Source repository.
In our case (UE40ES5700) it would be UExxES6xxx.zip. For other ES models, it would be UNxxES8xxx.zip.
But these two are exactly the same, except the following:
1. E8 and E6 have slightly different VDLinux kernels 2. There is an additional OR1200.ZIP for the E8
The only files (~150) which are different are listed HERE.
After download, do test the downloaded zip archive with:
$ unzip -t UExxES6xxx.zip
If you are curious to see detailed info of what's inside the ZIP archive before unzipping, do this:
$ unzip -Z UExxES6xxx.zip ...
Extract the ZIP file to a directory where you would like to keep your sources.
$ cd /zarm/src/ $ unzip UExxES6xxx.zip -d UExxES6xxx
This will unzip the following:
alsa-lib-1.0.23.tgz Advanced Linux Sound Architecture (audio and MIDI)
ATK.tgz Accessibility Toolkit (screen User Interface)
binutils-2010q1.tgz A collection of binary tools (ld, as, nm, objdump etc.)
BROADCOM-bthid.tgz Broadcom Bluetooth HID drivers (keyboards, mice, game controllers)
BROADCOM-btusb.tgz Broadcom Bluetooth USB drivers (keyboards, mice, game controllers)
busybox-1.18.1.tgz Busybox combines many common UNIX utilities into a single executable
Cairo.tgz A 2D graphics library (X Window, quartz, win32, PDF, PS, SVG file output)
FFMPEG.tar.gz A cross-platform solution to record, convert and stream audio and video
glibc-2.11-2010q1.tgz The GNU C Library
Glibmm.tgz A C++ interface for the popular cross-platform library Glib
gnutls-2.6.4.tar.gz GNU Transport Layer Security Library (SSL, TLS and DTLS protocols)
iptables-1.4.10.tgz Linux kernel firewall
libgcrypt-1.4.5.tar.gz A general purpose cryptographic library
libgpg-error-1.7.tar.gz A library that defines common error values for all GnuPG components
LIBGPHOTO2.tar The core library designed to allow access to digital camera by external programs
LibMMS_0.6.2.tgz A library for parsing mms:// and mmsh:// type network streams
libsoup.20120109.tgz An HTTP client/server library for GNOME
libtasn1-2.5.tar.gz The ASN.1 library used by GnuTLS
LIBUSB.tar A C library that gives applications easy access to USB devices
Pango.tgz A library for layout and rendering of multi-language text
RALINK_RTNET5572STA_V_2_5_0_1.tgz Ralink RTnet RT5572 (Wifi USB dongle drivers)
RALINK_RTUTIL5572STA_V_2_5_0_1.tgz Ralink RTnet RT5572 (Wifi USB dongle utilities)
readme.zip HOW_TO_BUILD_X9X10.txt
SDL.tar.gz Simple DirectMedia Layer (a multimedia library written in C)
uvc.tar.gz USB Video Class (streaming webcams, digital cameras etc)
v4l2.tar.gz Video4Linux-2 (a video capture API for Linux)
VDLinux_2.6.35.11.tgz Kernel sources (VDLinux, Tuxera NTFS, RFS, LinuStoreIII, FSR)
webkit-gtk.20120109.tgz WebKit is an open source web browser engine (Safari, Chrome)
WIRELESSTOOLS_29.tgz Wireless Tools (iwconfig, iwlist, etc)
xfsprogs-3.1.5.tgz A set of command-line tools to manage XFS filesystems
Which of these do you really need? Now that is the million dollar question.
The simple and stupid answer is, that it depends on what you want to do.
a) If you need to compile some simple C-code using standard clibs and linux system calls, you probably don't need any. (E.g. helloworld.c) b) If you need to compile your own Kernel module (hellok.ko) you probably need: VDLinux_2.6.35.11.tgz c) If you want to compile your own Kernel image (uImage) you probably only need: VDLinux_2.6.35.11.tgz d) If you want to compile your own library object (somelib.so) you probably only need: VDLinux_2.6.35.11.tgz ++++ e) If you need to compile your own device driver you probably need: <the device driver sources> VDLinux_2.6.35.11.tgz ? glibc-2.11-2010q1.tgz ? Glibmm.tgz f) If you want to compile your own TV DSP (exeDSP, micom etc) you're screwed (by Samsung) since there are no publicly available sources for that.
The better answer is, that it depends on how your kernel image has been setup
and how you intend setup your compilation environment. We really don't want to
have to setup and compile all sources from scratch, just to make a simple kernel
module. The way to do that is by telling your cross-compiler where to find the
kernel header files that it has to use the same configuration as that used to
compile your kernel.
So for further details, we look at HOW_TO_BUILD_X9X10.txt inside the readme.zip. This file explains, in a very screwy way, how to build each of the items included on the UExxES6xxx.zip file. In fact you should not rely blindly on this info.
For example:
... [ Building linux kernel ] * Source code name : VDLinux_2.6.35.11.tgz * Unpack the kernel tarball and cd into it. * Run "cd VDLinux_2.6.35.11/linux-2.6.35.11/". * Run "cp -ar arch/arm/configs/X10P_defconfig_release .config". * Run "make oldconfig". * Run "make uImage". [ Building busybox ] * Source code name : busybox-1.18.1.tgz * Unpack the busybox tarball and cd into it. * Run "make clean". * Run "cp -ar configs/busybox_config .config". * Run "make ARCH=arm CROSS_COMPILE=arm-v7a8v2r2-linux-gnueabi- oldconfig". * Run "make ARCH=arm CROSS_COMPILE=arm-v7a8v2r2-linux-gnueabi- CONFIG_PREFIX=../temp_rootfs install". * Run "cd ../temp_rootfs/bin". ...
Clearly, for general purpose use we need at least the VDLinux sources installed.
So we extract this in the same directory with:
$ (tar -zxvf VDLinux_2.6.35.11.tgz >vdlinux_tar.log) 2>&1
Here we have redirected the output to a log file for reference, while any
errors will be shown on screen. This will create VDLinux_2.6.35.11
with the following sub-directories:
linux-2.6.35.11 TUXERA_NTFS RFS_3.0.0_b043-LinuStoreIII_1.2.0_b039-FSR_1.2.1p1_b139_RTM
WIP!!
(F) Compiling a Kernel module
Introduction
Linux is a monolithic kernel, where all of the code and data that makes up the
image are linked into one binary and loaded into memory.
"A very useful part of the Linux kernel architecture is the support for
loadable kernel modules. These modules allow the otherwise monolithic kernel
to be split up into smaller components that can later be loaded as required,
allowing the kernel to ship with support for a wide range features but only
load those that are needed.
Kernel modules also ease the development of new features such as file systems
or device drivers, as a new experimental modules can be quickly built, loaded
into a basic kernel, exercised, and then unloaded. This is much faster then
the build, flash, restart process that would otherwise be required."
The main reason for this, is that you don't have to re-compile the entire
kernel from the full kernel source tree. It should be enough to just have
the kernel header files, in order to build a module.
Internally a module is a standard ELF executable file with a .ko extension and
a few special sections such as .modinfo for the module metadata and .init.text
for the module initialization code. (This is normally done by linking
yourprogram.o with vermagic.o, which is transparent to the developer.)
A nice thing about modules being ELF files is that they can be generated
and inspected by standard tools.
In the current 2.6 series, the ARM kernel is laid out as follows:
Start End Contents ----------------------------------------------------------------------------- 0xFF000000 0xFFFFFFFF Vector page, DMA region, and others VMALLOC_END 0xFEFFFFFF free VMALLOC_START VMALLOC_END vmalloc() / ioremap() space PAGE_OFFSET high_memory The Linux kernel TASK_SIZE PAGE_OFFSET-1 Kernel module space (16 MB) 0x00001000 TASK_SIZE-1 User space (~3 GB) 0x00000000 0x00001000 Vector page / Null pointer trap ----------------------------------------------------------------------------- PAGE_OFFSET = 0xC0000000 TASK_SIZE = 0xBF000000
Note that these are virtual addresses, which are different than the physical address space of the board.
The HelloWorld-1 kernel module
We will attempt to build two kernel modules. One very basic in "Hello World"
style to see that it compiles and works,
and another only slighlty more complicated to check if kernel debugfs works.
Any module which want to send info to kernel messages ( /proc/kmsg ) have
to include the kernel.h header file. What is actually shown depend on the
current kernel debug level as set in /proc/printk... <== check!
./include/linux/kernel.h:
... #define KERN_EMERG "<0>" /* system is unusable */ #define KERN_ALERT "<1>" /* action must be taken immediately */ #define KERN_CRIT "<2>" /* critical conditions */ #define KERN_ERR "<3>" /* error conditions */ #define KERN_WARNING "<4>" /* warning conditions */ #define KERN_NOTICE "<5>" /* normal but significant condition */ #define KERN_INFO "<6>" /* informational */ #define KERN_DEBUG "<7>" /* debug-level messages */ ...
You can see your current kernel debug level with either:
shell> sysctl -a ... kernel.printk= ... OR shell> cat /proc/loglevel ??? <== check!! shell> cat /proc/printk kernel.printk = 4 4 1 7
You can read more about these here:
modinfo -p ${modulename} echo -n ${value} > /sys/module/${modulename}/parameters/${parm}
Now, to the actual kernel module code.
hellok1.c:
#include <linux/module.h> /* Needed by all modules */ #include <linux/kernel.h> /* Needed for KERN_ALERT */ MODULE_LICENSE("GPL"); MODULE_AUTHOR("E:V:A 2013"); MODULE_DESCRIPTION("Demo kernel module for MST-X10P (ARM Cortex A9)"); int init_module(void) { printk(KERN_ALERT "E:V:A is in the Kernel!\n"); return 0; } void cleanup_module(void) { printk(KERN_ALERT "Goodbye TV Kernel!\n"); }
Now that was the trivial part!
The Makefile
The most difficult part of compiling a kernel module, is setting up the
Makefile that contain all the compilation instructions, locations and
parameters needed for your cross-compiler. It is good to be familiar with
the "Makefile" language, as it is tab and space sensitive, and have many other
pitfalls, that can easily be overseen. The Makefile is also closely connected
with how your kernel have been compiled, so if you're missing kernel support
for your modules features (e.g. debugfs), you will not get anything...
(It should be noted that Makefile may also contain the functionality of
Kbuild, which is very similar, but whose structure is even more simple.
We will not cover the details of this here.)
Makefile:
ifneq ($(KERNELRELEASE),) obj-m += hellok1.o else KERNELDIR := /cygdrive/d/zarm/vdl_kernel/linux/linux-2.6.35.11/ all: $(MAKE) -C $(KERNELDIR) M=$(PWD) modules clean: rm -fr ./.tmp_versions modules.order ls -al ./mods endif
NOTE: The code above contains hidden tabs, so make sure they're still there if you decide to copy & paste the code from above!
The HelloWorld-2 kernel module
Now that we have gained some intellectual kernel meat, we can design a slightly more useful kernel module. One that actually does something.
The following code is an example kernel module that shows the life cycle and provides a function to user space over debugfs. It creates a new file in /sys/kernel/debug/hello/ping that can be opened and read from user space. Reading this file gives a short message that includes the number of times the file has been opened. All original comments have been removed, but can be found in [3].
hellok2.c:
#include <linux/init.h> #include <linux/module.h> #include <linux/debugfs.h> #include <linux/seq_file.h> MODULE_LICENSE("Dual BSD/GPL"); static struct dentry *root_dir; static int calls; static int hello_print(struct seq_file *s, void *p) { seq_printf(s, "Called %d times\n", ++calls); return 0; } static int hello_open(struct inode *inode, struct file *file) { return single_open(file, hello_print, inode->i_private); } static const struct file_operations hello_fops = { .open = hello_open, .write = NULL, .read = seq_read, .llseek = seq_lseek, .owner = THIS_MODULE, }; static int hello_init(void) { printk(KERN_ALERT "Hello world\n"); root_dir = debugfs_create_dir("hello", NULL); debugfs_create_file("ping", 0444, root_dir, NULL, &hello_fops); return 0; } static void hello_exit(void) { debugfs_remove_recursive(root_dir); printk(KERN_ALERT "Goodbye Dear Module\n"); } module_init(hello_init); module_exit(hello_exit);
The Makefile for this is your homework, but a good hint is that the tricky part this time, is not the Makefile, but enabling DEBUGFS in your kernel, if not already enabled...
WIP!! ....
References
CodeSourcery Application Notes:
[1] "Flying Introduction to Linux Kernel Development" (AN001)
[2] "Using Sourcery CodeBench to Debug the Linux Kernel" (AN002)
[3] "Using Sourcery CodeBench to Develop and Debug a Linux Kernel Module" (AN003)
[4] "GNU make manual"
(Z) Place Holder Template
Bah!