[[PageOutline]] = Linux Kernel Development = This page is for new or inexperienced developers wanting to work directly on the linux kernel. [=#linuxsource] == Kernel sources == When choosing a kernel source you need to determine what support you are interested in. Gateworks recommends using our Gateworks downstream vendor kernel if you are needing full hardware support as the mainline Linux kernel is still lacking certain IMX6 support. == Newport Kernel == It is highly recommended to visit the [wiki:newport/bsp#kernel Newport BSP page kernel section] for more information about the Newport kernel. === Gateworks downstream vendor kernel === Gateworks maintains a downstream Linux kernel that contains patches from Freescale and Gateworks to add support for Ventana including some items that have not made it into mainline Linux yet. * [https://github.com/Gateworks/linux-imx6 source] * [http://svn.gateworks.com/ventana/images/gateworks-linux-imx6-3.14.48.tar.gz gateworks-linux-imx6-3.14.48.tar.gz] - prebuilt tarball * see [#backports below] if needing the latest wireless drivers from linux-wireless on top of the older Gateworks downstream vendor kernel Our pre-built Gateworks downstream vendor kernel is a build artifact of our Yocto BSP and contains the following: * drivers we feel are important for our user base * wireless drivers from the Linux backports project * firmware for various devices that require run-time firmware loading * kernel headers Our kernel source has a default config file (arch/arm/configs/gwventana_defconfig) which which we use but keep in mind that in general wireless drivers and subsystems are not defined there because those modules come from linux-backports instead. === Mainline upstream linux kernel === The mainline Linux kernel is missing the following support (which is present in the Gateworks vendor kernel): * IMX6 video capture (this is slowly being worked on but not yet present as of 4.2) * adv7393 analog video output (GW54xx) * HW crypto support * IMX6 GPU driver (there is work ongoing on an open-source reverse engineered Vivante driver called [https://github.com/laanwj/etna_viv etna_viv]) * VPU support (technically, the upstream coda driver does support the chips-and-media VPU but not in a way that gstreamer can utilize it) See also: * [wiki:ventana/#mainline-linux Gateworks mainline linux details and patches] * http://git.kernel.org/cgit/linux/kernel/git/torvalds/linux.git - source * https://www.kernel.org/ - source archives * http://kernelnewbies.org/LinuxVersions - Linux version info [=#toolchain] == Toolchains == A toolchain is a set of compiler tools (typically gcc) and libraries necessary for compiling and linking source (and possibly debugging, diss-assembling, etc). Typically this includes the following (for the GNU C Compiler): * ar - linker * as - assembler * c++/g++ - C++ compiler * gcc - C compiler * ld - linker * nm - list symbols from object files * strip - strips debug info from object files * objcopy - copy and translate object files * objdump - display info from object files * ranlib - generate index to archive * lib/lib* - stdc libraries * include/ - stdc library headers The kernel (which is written entirely in ANSI-C) is compiled with gcc and does not link against the stdc library. You likely have one of the following toolchains to work with: * toolchain from an OpenWrt build directory * toolchain from a prebuilt OpenWrt BSP SDK * toolchain from a Yocto build directory * toolchain from a prebuilt Yocto BSP SDK * pre-built toolchain from somewhere else, like Android [=#rootfs] == Userspace and root filesystem == Userspace refers to anything in a Linux based OS which is 'not' the kernel. After initialization, the Linux kernel mounts the rootfs and executes PID1 (/sbin/init) which is the start of userspace. The init process and any processes it launches are part of userspace. When applications act on device files such as /dev/sda they use an ioctl API to interact with kernel functions from userspace. A useful way to determine the uses per directory is to execute a {{{man hier}}} on your Ubuntu system. A root filesystem (sometimes referred to as 'a userspace') contains everything you need for a Linux based OS other than the kernel itself. The root filesystem could contain the kernel, but only if the bootloader mounts it and launches it from the rootfs (ie the Gateworks Ventana product family). Note that kernel modules are contained on the root filesystem but they are not considered userspace (yet the insmod/rmmod/modprobe apps that load/remove them are). You likely have one of the following userspaces you want to work with: * OpenWrt root filesystem * Yocto root filesystem * Android root filesystem * Ubuntu root filesystem In general, you should be able to mix and match kernels and userspace within reason, but note that certain Linux based OS's may require specific kernel functionality (ie Android requires several Android specific kernel features to exist). When working on mainline Linux patches, Gateworks developers often use either an OpenWrt userspace root filesystem or a Yocto userspace root filesystem depending on their needs. [=#building] == Building the Linux kernel (out-of-tree) == Building the Linux kernel 'out-of-tree' refers to building it outside of the Board Support Package development environment. Each BSP that Gateworks provides builds the kernel for you, but doing constant kernel development within those BSP's may not be very time efficient. Gateworks developers typically do kernel development out-of-tree and boot the kernel over the network to speed up development. If working with kernel modules, one could remove the module (rmmod), download it, install it (insmod) again and test and avoid constantly rebooting the board. Often its just as quick to build a driver static in the kernel, configure your board for network booting, and just rebuild/reboot continually. '''Prerequisites:''' - Linux development host: Gateworks uses and supports Ubuntu which is used here as an example, but other Linux variants can work as well - Toolchain for the CPU architecture of the boards you are working with: * Ventana uses the Freescale IMX6 SoC which has ARM Cortex-A9 cores with NEON SIMD support. You can download our pre-built OpenWrt toolchain [http://dev.gateworks.com/openwrt/14.08/imx6/OpenWrt-Toolchain-imx6-for-arm_cortex-a9+neon-gcc-4.8-linaro_uClibc-0.9.33.2_eabi.tar.bz2 here] * Laguna uses the Cavium cns3xxx SoC which has ARM11 MP-Core cores Steps to build the Gateworks kernel for the Ventana family using the Gateworks OpenWrt toolchain: 1. Install pre-requisites: {{{#!bash apt-get install build-essential ncurses-dev bc u-boot-tools liblzo2-dev lzop git }}} * typically 'build-essential' provides enough for compiling, however we need a few other things for kernel development: - ncurses-dev is needed for menuconfig - u-boot-tools, bc, and lzop are needed for uImage - git is needed for checking out the source 2. Obtain and install compiler toolchain: * For Ventana, you can use the pre-built Gateworks OpenWrt 14.08 BSP tailored to the ARM Cortex-A9 CPU used in the IMX6 SoC: {{{#!bash wget http://dev.gateworks.com/openwrt/14.08/imx6/OpenWrt-Toolchain-imx6-for-arm_cortex-a9+neon-gcc-4.8-linaro_uClibc-0.9.33.2_eabi.tar.bz2 tar -xvf OpenWrt-Toolchain-imx6-for-arm_cortex-a9+neon-gcc-4.8-linaro_uClibc-0.9.33.2_eabi.tar.bz2 }}} 3. Obtain Linux kernel source (see [#linuxsource above] to help you decide which kernel version you should use): * for the '''Gateworks Linux 3.14.x''' based downstream vendor kernel (with full Ventana support including video capture which hasn't made it fully into mainline yet): {{{#!bash git clone https://github.com/Gateworks/linux-imx6.git cd linux-imx6 git checkout gateworks_fslc_3.14_1.0.x_ga }}} * for mainline '''Linux v4.1''' for example (which is missing video capture support for IMX6/Ventana): {{{#!bash git clone git://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git cd linux git checkout v4.1 }}} 4. Setup shell env for building: * Note that the paths here are dependent on the toolchain you installed. The following is for the pre-built Gateworks OpenWrt 14.08 BSP toolchain: {{{#!bash export STAGING_DIR=../OpenWrt-Toolchain-imx6-for-arm_cortex-a9+neon-gcc-4.8-linaro_uClibc-0.9.33.2_eabi TOOLCHAIN=toolchain-arm_cortex-a9+neon_gcc-4.8-linaro_uClibc-0.9.33.2_eabi PATH=$PATH:$STAGING_DIR/$TOOLCHAIN/bin export INSTALL_MOD_PATH=install export INSTALL_HDR_PATH=install export ARCH=arm export CROSS_COMPILE=arm-openwrt-linux- }}} * Note that STAGING_DIR is something required by the OpenWrt toolchain... your toolchain may differ * The INSTALL_MOD_PATH env var is used by the modules_install and firmware_install make targets to specify the directory to install modules/firmware into * The ARCH and CROSS_COMPILE env args are required for proper cross-compilation using your toolchain * Some troubleshooting steps: {{{#!bash echo $ARCH #should return arm }}} {{{#!bash which ${CROSS_COMPILE}gcc #is this your compiler }}} {{{#!bash ${CROSS_COMPILE}gcc -v #is target: your desired architecture }}} {{{#!bash echo $PATH #have you appended the appropriate parameters to your path. When in doubt start new shell }}} 5. Configure the kernel: * for the '''Gateworks Linux 3.14.x''' based downstream vendor kernel start with {{{gwventana_defconfig}}} * {{{#!bash make gwventana_defconfig }}} * for mainline '''Linux v4.1''' start with the {{{imx_v6_v7_defconfig}}}: {{{ #!bash make imx_v6_v7_defconfig }}} * Optional, modify kernel: {{{#!bash make menuconfig }}} * The menuconfig make target launches the ncurses based (serial console) Linux kernel menu configuration tool so that you can add or adjust the support to your needs. A common change to the default kernel configurations above would be to add support for a USB based device, or wireless (802.11) support for example. 6. Build kernel: {{{#!bash LOADADDR=0x10008000 make uImage modules dtbs modules_install }}} * the default make target will build zImage, modules, and dtbs - we want uImage, modules and dtbs * when building a multi-arch kernel, the build system needs to know the load address to put in the u-boot image header which you provide via the LOADADDR env var. For IMX6 its 0x10008000 * the firmware_install make target can also be specified if you need specific firmware to be placed in $INSTALL_MOD_PATH/lib/firmware * The uImage make target builds a U-Boot image of the kernel * The dtbs make target builds the device-tree binaries needed to boot the Ventana kernel (not used for non device-tree kernels) * The modules_install make target installs the kernel modules to the INSTALL_MOD_PATH directory * After building and copying the uImage and dtbs to install/boot, you can copy or extract the contents of the install directory to your Linux root filesystem taking care to make the user and group root * headers will be in the install dir 6. Copy additional artifacts: {{{#!bash mkdir $INSTALL_MOD_PATH/boot cp arch/arm/boot/uImage arch/arm/boot/dts/imx6*gw*.dtb $INSTALL_MOD_PATH/boot }}} If you wish to make a tarball of this kernel relative to the root fs: {{{#!bash tar -C $INSTALL_MOD_PATH --owner=0 --group=0 -cvzf linux-4.1.tar.gz . }}} If you need kernel headers for development you can build them via: {{{#!bash make headers_install }}} * headers will be in INSTALL_HDR_PATH which we set to the install subdir above If you wish to add additional drivers from a newer kernel (for example, you are using the 3.14.x Gateworks downstream vendor kernel but wish to have updated wireless drivers) see [#backports below]. [=#backports] == Building the Latest Kernel Modules - Wireless Backports == Because we don't use mainline linux, but require the latest drivers in wireless, we use the {{{backports}}} project. For more detail on this project, please visit their [https://backports.wiki.kernel.org/index.php/Main_Page documentation] site. In order to build this, you will need a kernel tree already built. In this example, I will assume the {{{gateworks_fslc_3.14_1.0.x_ga}}} kernel is being used. 1. Change into the kernel tree directory, making sure it is built using the example shown in the [wiki:linux/kernel#building building section above]. {{{#!bash cd gateworks_fslc_3.14_1.0.x_ga make gwventana_defconfig etc... }}} 2. Grab the backports version you want to use and {{{cd}}} into it. This example will use the one currently used for our Yocto BSPs. {{{#!bash wget https://www.kernel.org/pub/linux/kernel/projects/backports/2016/01/22/backports-20160122.tar.gz tar xzf backports-20160122.tar.gz cd backports-20160122 }}} 3. [OPTIONAL] You may have to patch the backports project, depending on the version being used {{{#!bash wget https://raw.githubusercontent.com/Gateworks/meta-gateworks/fido/recipes-kernel/compat-wireless/compat-wireless-all/0001-disable_kconf.patch wget https://raw.githubusercontent.com/Gateworks/meta-gateworks/fido/recipes-kernel/compat-wireless/compat-wireless-all/0002-add-KLIB_CONFIG.patch wget https://raw.githubusercontent.com/Gateworks/meta-gateworks/fido/recipes-kernel/compat-wireless/compat-wireless-all/add_db_txt.patch patch -p1 < 0001-disable_kconf.patch # Used if no kconfig available (generally never needed) patch -p1 < 0002-add-KLIB_CONFIG.patch # Used if config is not located in kernel directory patch -p1 < add_db_txt.patch # Used if needing static wireless regulatory database }}} 4. Configure shell for cross compiler (please see [wiki:linux/kernel#building the building section] for more details) {{{#!bash export STAGING_DIR=../OpenWrt-Toolchain-imx6-for-arm_cortex-a9+neon-gcc-4.8-linaro_uClibc-0.9.33.2_eabi TOOLCHAIN=toolchain-arm_cortex-a9+neon_gcc-4.8-linaro_uClibc-0.9.33.2_eabi PATH=$PATH:$STAGING_DIR/$TOOLCHAIN/bin export INSTALL_MOD_PATH=install export ARCH=arm export CROSS_COMPILE=arm-openwrt-linux- export KLIB=.. export KLIB_BUILD=.. export KLIB_CONFIG=.. }}} Notice that the {{{KLIB}}} variables are new; They refer to the location of the raw kernel, location where it is built, and location to the config file. 5. Make menuconfig to select drivers you want the latest of, then build. {{{#!bash make menuconfig make modules }}} 6. [OPTIONAL] Locate the .ko's and copy them to the built kernel {{{#!bash cp --parent $(find -name "*.ko") ../ }}} And that's it! If you tar the kernel up, make sure to remove the backports directory as each {{{.ko}}} will be double counted if you already copied the {{{.ko's}}} to the kernel tree. Please see the [wiki:linux/kernel#updating updating section] for details on how to update a target's kernel. == Kernel Module Commands == * depmod - builds module dependency database * modprobe loads module and all dependecies * insmod loads module but NO depedencies See Linux documentation for more information. [=#updating] == Updating the kernel dtbs and modules on a running target == If you want to update the kernel, dtbs, and modules on a running target using the tarball created after building the kernel (see above), you can do this by booting and using: {{{#!bash # download kernel specific tarball suitable for booted kernel KERNEL=$(uname -r) URL=http://192.168.1.165/tftpboot/ventana/ rm -f /tmp/linux-$KERNEL.tar.gz wget -P /tmp $URL/linux-$KERNEL.tar.gz # untar appropriately if [ -d /etc/config ]; then # OpenWrt stores modules in a flat tree echo "OpenWrt Filesystem" ( cd /; tar -xvzf /tmp/linux-$KERNEL.tar.gz ) find /lib/modules/$KERNEL -name *.ko -exec mv {} /lib/modules/$KERNEL \; else ( cd /; tar -xvf /tmp/linux-$KERNEL.tar.gz ) fi depmod -a sync }}} [=#netboot] == Booting the kernel from the network == The bootloader's job is to load the linux kernel and execute it. Often during kernel development its advantageous to boot the kernel from the network to create very quick edit/build/boot cycles. This can be accomplished in a variety of ways depending on what you want to come from the network, the kernel, the device-tree blobs, the root filesystem etc. During kernel development usually its just the kernel and device-tree blobs that are needed to boot over the network and using a flash based userspace filesystem is fine. To do this using Ventana as an example: {{{#!bash # boot kernel+dtbs over network via tftp, using NAND filesystem tftp ${loadaddr} ${prefix}uImage && \ tftp ${fdt_addr} ${prefix}${fdt_file2} && \ fdt addr ${fdt_addr} && \ fdt boardsetup && \ setenv bootargs console=${console},${baudrate} root=ubi0:rootfs ubi.mtd=2 rootfstype=ubifs ${video} ${extra} && \ bootm ${loadaddr} - ${fdt_addr} # boot kernel+dtbs over netowrk via tftp, using MMC filesystem tftp ${loadaddr} ${prefix}uImage && \ tftp ${fdt_addr} ${prefix}${fdt_file2} && \ fdt addr ${fdt_addr} && \ fdt boardsetup && \ setenv bootargs console=${console},${baudrate} root=/dev/mmcblk0p1 rootfstype=ext4 rootwait rw ${video} ${extra} && \ bootm ${loadaddr} - ${fdt_addr} # boot kernel_dtbs over network via tftp, using USB filesystem tftp ${loadaddr} ${prefix}uImage && \ tftp ${fdt_addr} ${prefix}${fdt_file2} && \ fdt addr ${fdt_addr} && \ fdt boardsetup && \ setenv bootargs console=${console},${baudrate} root=/dev/sda1 rootfstype=ext4 rootwait rw ${video} ${extra} && \ bootm ${loadaddr} - ${fdt_addr} }}}