COM iMX25 Linux

From Wiki-DB
Jump to navigationJump to search


Linux virtual machine for development

Introduction

For cross developing of applications we provide virtual machines with preinstalled toolchains. Choose the virtual machine which fits to your DHCOM target (Debian 8 on target -> Debian 8 virtual machine). Debian 8 does include support for architecture armhf and armel (Debian 6 only armel). By default Debian 8 is configured for armhf. The sections Code Examples for Userspace-Applications to Access SPI, I2C, GPIOs, and more and Booting via NFS apply for Debian 6 and Debian 8.

Debian 9 "Stretch" VM image (for VMware and VirtualBox)

Get the virtual machine

Remark: For security reasons, you must set your own password when starting the virtual machine for the first time:
  1. Enter default user devel password (devel)
  2. Enter default user devel password again (devel)
  3. Enter your own user devel password
  4. Enter your own user devel password again
Version: File: Changes:
v2.1.Vx Debian Stretch v2.1.Vx.zip - Add Docker
- Python updated to version 3.6.9
- Add ARMv7 Cross-Compiler gcc v10.2
- Enable Copy & Paste and Drag & Drop for files
v2.0.Vx Debian Stretch v2.0.Vx.zip - First release version of Debian 9 VM

Installed Toolchains

  • Used for building the Linux Kernel for our ARMv7 DHCOM devices.
  • ARM GCC 10.2 (available since v2.1.Vx)
armhf: CROSS_COMPILE=/opt/gcc-arm-10.2-2020.11-x86_64-arm-none-linux-gnueabihf/bin/arm-none-linux-gnueabihf-
  • ARM GCC 8.3
armhf: CROSS_COMPILE=/opt/gcc-arm-8.3-2019.03-x86_64-arm-linux-gnueabihf/bin/arm-linux-gnueabihf-
  • Linaro GCC 7.4
armhf: CROSS_COMPILE=/opt/gcc-linaro-7.4.1-2019.02-x86_64_arm-linux-gnueabihf/bin/arm-linux-gnueabihf-
  • Linaro GCC 6.3
armhf: CROSS_COMPILE=/opt/gcc-linaro-6.3.1-2017.05-x86_64_arm-linux-gnueabihf/bin/arm-linux-gnueabihf-
  • Linaro GCC 4.9
armhf: CROSS_COMPILE=/opt/gcc-linaro-4.9-2014.11-x86_64_arm-linux-gnueabihf/bin/arm-linux-gnueabihf-
  • Used for building the Linux Kernel for our ARMv5 DHCOM devices.
  • CodeSourcery GCC 4.5
armel: CROSS_COMPILE=/opt/CodeSourcery-2011.03-41/bin/arm-none-linux-gnueabi-

Yocto Builds

Note (only concerning v2.0.Vx): If you are going to set up any DH electronics Yocto project by using the repo tool, you need to install Python version 3.6 or later.

This versions are not provided by official Debian Stretch package repositories. To manually install Python 3.6.9 , please follow the instructions:

$: sudo apt install libsqlite3-dev
$: wget https://www.python.org/ftp/python/3.6.9/Python-3.6.9.tgz
$: tar xvf Python-3.6.9.tgz
$: cd Python-3.6.9
$: ./configure --enable-optimizations --enable-shared
$: make -j8
$: sudo make install
$: sudo /sbin/ldconfig -v

Debian 8 "Jessie" VM image (for VMware)

Get the virtual machine

Version: File: Changes:
v1.3 Debian Jessie v1.3.zip - Debian Security updates
- Compatibility VMware player 5.0
- Ready for yocto build
- Build environment for DHCOM i.MX6 Qt5.7.1 / Qt5.9.1
- Add some useful tools
v1.2 Debian Jessie v1.2.zip - Debian Security updates
- Qt Creator + Support for imx6 modules + Demos
- Update elbe to v1.0
- Add some tools / editors
v1.1 Debian Jessie v1.1.zip - Compatibility VMware player 6.0
v1.0 Debian Jessie v1.0.zip - New Debian 8 VM

Installed Toolchains

  • Used for building the Linux Kernel for our ARMv7 DHCOM devices.
  • Debian Multiarch Cross Toolchain GCC 4.9
armhf: CROSS_COMPILE=arm-linux-gnueabihf-
The Cross Toolchains is preinstalled. They should be used for cross development of native Linux applications. They are downloaded and installed with the Debian Package Manager.
Install directory is /usr/bin/. Please have a look at the preconfigured Examples for cross development using the Eclipse IDE.
  • Linaro GCC 4.9
armhf: CROSS_COMPILE=/opt/gcc-linaro-4.9-2014.11-x86_64_arm-linux-gnueabihf/bin/arm-linux-gnueabihf-
  • Used for building the Linux Kernel for our ARMv5 DHCOM devices.
  • Debian Multiarch Cross Toolchain
armel: CROSS_COMPILE=arm-linux-gnueabi-
The Cross Toolchains is preinstalled. They should be used for cross development of native Linux applications. They are downloaded and installed with the Debian Package Manager.
Install directory is /usr/bin/. Please have a look at the preconfigured Examples for cross development using the Eclipse IDE.
  • CodeSourcery GCC 4.5
armel: CROSS_COMPILE=/opt/CodeSourcery-2011.03-41/bin/arm-none-linux-gnueabi-

Qt5 Development

Qt5.5.1 prebuilt and preinstalled

We provide the prebuilt Qt5.5.1 libraries including WebEngine (only QtQuick) and WebKit in /work/qt5/sysroot/. This directory contains a Debian 8 based rootfilesystem which is prepared for DHCOM i.MX6, the matching sysroot (*-dev packages), and the Qt5.5.1 libraries installed.

Qt5.7.1

We support the latest Qt5.7.1 on our DHCOM i.MX6 and DHCOM am335x. Please download and install the qmake-sysroot-mx6-crossarmhf_5.7.1-1.0 or qmake-sysroot-am33-crossarmhf_5.7.1-1.0 package to the DebianVM:

  1. open a terminal
  2. # for i.MX6: wget https://dl.dropboxusercontent.com/u/19433555/DHCOM/imx6/qmake-sysroot-mx6-crossarmhf_5.7.1-1.0_amd64.deb
  3. # for AM335x: wget https://dl.dropboxusercontent.com/u/19433555/DHCOM/am335x/qmake-sysroot-am33-crossarmhf_5.7.1-1.0_amd64.deb
  4. install the package
  5. # sudo dpkg -i qmake-sysroot-mx6-crossarmhf_5.7.1-1.0_amd64.deb
  6. now the sysroot and qmake is ready to use
  7. path to qmake is /work/qt5_mx6_armhf/sysroot/usr/local/qt5.7.1/bin/qmake

Build a Qt5 Application via console

  1. open a terminal
  2. navigate to your Qt5 sources
  3. # /work/qt5/sysroot/usr/local/qt5.5.1/bin/qmake your_own_app.pro
  4. # make

Qt Creator

  1. Start Qt Creator IDE
  2. Open demo project TwoLED: /work/qt5_Demos/TwoLED
  3. There you can find the configurations for your own project.

Debian 6 "Squeeze" VM image (for VMware)

Get the virtual machine

Version: File: Changes:
v1.5 Debian Squeeze v1.5pw.zip - Update VMware Tools
- DH UBI-Tools
- Language: English
- System updates
v1.4 Debian Squeeze v1.4pw.zip - ELBE v0.3.1
- ELDK 4.2
- Qt Creator 2.6.1 + Qt target libs 4.7.2
- System updates
v1.3 Debian Squeeze v1.3.zipx - Mono 2.10
- mtd-utils
- System updates
v1.2 Debian Squeeze v1.2.zipx - Emdebian Toolchain gcc 4.3 / g++ 4.3 (arm-linux-gnueabi-...)
- TortoiseHg + TortoiseHg for Nautilus
- Add Plugin "REST Client" in Iceweasel
v1.1 Debian Squeeze v1.1.zipx - Update Eclipse Indigo with CDT 8.0
- Add demo project "crosshelloworld"
v1.0 Debian Squeeze.zipx - First Release
- CodeSourcery Toolchain (arm-none-linux-gnueabi-...)
- Eclipse Helios & Indigo

Installed Toolchains

  • Used for building the Linux Kernel for our ARMv5 DHCOM devices.
  • Debian Multiarch Cross Toolchain GCC 4.3
armel: CROSS_COMPILE=arm-linux-gnueabi-
The Cross Toolchains is preinstalled. They should be used for cross development of native Linux applications. They are downloaded and installed with the Debian Package Manager.
Install directory is /usr/bin/. Please have a look at the preconfigured Examples for cross development using the Eclipse IDE.
  • CodeSourcery GCC 4.5
armel: CROSS_COMPILE=/opt/CodeSourcery/Sourcery_G++_Lite/bin/arm-none-linux-gnueabi-

Setting up a Eclipse Cross Executable Project:

  • Use Eclipse Indigo (version 3.7.1) for your project.
  • Create a new C++ Project and choose as Executable Project type Cross-Compile Project and as Toolchains Cross GCC
  • Click the Button "Next" and specify under Tool command path the Toolchain path.
  • CodeSourcery:
Folder "/opt/CodeSourcery/Sourcery_G++_Lite/bin"
Prefix type "arm-none-linux-gnueabi-"
  • Emdebian Toolchain:
Folder "/usr/bin"
Prefix type "arm-linux-gnueabi-"

Use Virtualbox instead of VMware Player/Workstation

VMware Maschine mit VirtualBox starten (German)

Booting via TFTP/NFS

Prepare the virtual machine

  1. Setup nfs-kernel-server
    • Install thf nfs server: $ sudo apt-get install nfs-kernel-server
    • Create a nfsservice directory: $ mkdir /work/nfsroot
    • Place the root file system in the folder $ cd /work/nfsroot; sudo tar xf jessie....tar.gz
    • Remove network config from rootfs $ rm /work/nfsroot/etc/systemd/network/wired-dhcp.network
    • Check whether the line below is part of the /etc/exports file
    • /work/nfsroot X.X.X.0/255.255.255.0(rw,no_root_squash,no_subtree_check,insecure)
      • The X must be substituted by our network settings
    • Restart the nfs-server with 4 /etc/init.d/nfs-kernel-server restart
  2. Setup tftp-hpa server
    • Install a tftp server : $ sudo apt-get install tftpd-hpa
    • Create a tftp service directory: $ mkdir /work/tftp
    • Edit config: $ sudo vi /etc/default/tftpd-hpa
      • Take care that TFTP_DIRECTORY points to your tftp service directory, for example '/work/tftp'
    • Copy Kernel and DeviceTree into the tftp service directory
    • Restart the tftp-server with $ /etc/init.d/tftp-hpa restart

Setup the DHCOM Module for TFTP/NFS Boot

This example works with static IP addresses and is tested with DHCOM i.MX6 U-Boot 2015.10 and Kernle 4.4.38. It is possible to work with DHCP, too. For further information see https://www.kernel.org/doc/Documentation/filesystems/nfs/nfsroot.txt

  • Enter U-Boot console by pressing DEL/BACKSPACE on a RS232 terminal while switching on the power supply of the target
  • Set IP addresses
# env set serverip 192.168.178.90
# env set ipaddr 192.168.178.91
  • bootargs for nfs root (up to Debian Jessie)
# env set rootfs 'root=/dev/nfs nfsroot=192.168.178.90:/work/nfsroot/ ip=192.168.178.91:192.168.178.90::255.255.255.0:dhcom:eth0:none'
  • bootargs for nfs root (since Debian Stretch)
# env set rootfs 'root=/dev/nfs nfsroot=192.168.178.90:/work/nfsroot/,nfsvers=3 ip=192.168.178.91:192.168.178.90::255.255.255.0:dhcom:eth0:none'
  • load Linux kernel and devicetree with tftp (change filename and path to match you setup)
# tftp ${loadaddr} zImage
# tftp ${fdt_addr} dtbs/imx6dl-dhcom3B-pdk2.dtb
  • set bootargs and boot
# run linuxargs
# bootz ${loadaddr} - ${fdt_addr}
  • optional: save it to be permanent
# env set bootcmd 'tftp ${loadaddr} zImage; tftp ${fdt_addr} dtbs/imx6dl-dhcom3B-pdk2.dtb; run linuxargs; bootz ${loadaddr} - ${fdt_addr}
# env save

Code Examples for Userspace-Applications to Access SPI, I2C, GPIOs, and more

  • The following code samples are designed to get you started quickly with the device interfaces to SPI, I2C, GPIOs and more in Linux userspace applications.
  • Within Eclipse you can Import the provided projects:
  1. Execute ">File>Import ..."
  2. Navigate to ">General>Existing Projects into Workspace" within the import dialog
  3. Follow the dialog until you have finished.

Download Code Examples SPI, I2C, GPIOs and more

Included Demos:

  • SPI
  • I2C
  • GPIO
  • RTC
  • UART
  • Watchdog
  • ADC (only for i.MX25)

Download C++ HAL class library for SPI, I2C, GPIO, UART and physical address space access

Building your own Kernel

Sources for the iMX25 Linux Kernel v3.2.9 / v3.2.78:

How to build a kernel

Get sources from Github and build the linux kernel

1. Start a terminal on Linux
2. # git clone https://github.com/dh-electronics/linux-imx25.git
3. # git checkout BRANCH
(BRANCH=dev/3.2.9_dhcom or BRANCH=dev/3.2.78_dhcom)
4. # ARCH=arm CROSS_COMPILE=arm-none-linux-gnueabi- make imx25_dhcom_defconfig
5. # ARCH=arm CROSS_COMPILE=arm-none-linux-gnueabi- make uImage
  • Your new uImage file is available in arch/arm/boot


Sources older than February 2014

Sources for the iMX25 Linux Kernel v2.6.38:

Sources for the iMX25 Linux Kernel v3.2.9:

How to build a kernel

1. Start a terminal on Linux
2. Copy the above mentioned source files (linux-3.x.y.tar.bz2, .config, *.patch) into our work_path
3. # cd work_path
4. # tar xfjv linux-2.6.38.tar.bz2
5. # cd work_path/linux-2.6.38
6. # patch -p1 <linux-2.6.38_DHCOM_iMX25.patch
7. # cp .config work_path/linux-2.6.38
8. # ARCH=arm CROSS_COMPILE=arm-none-linux-gnueabi- make uImage
  • Your new uImage file is available in work_path/linux-2.6.38/arch/arm/boot

Update the kernel with U-Boot

The linux kernel will be updated by the U-Boot flash update.
1. Copy the uImage and uImage.env file onto a microSD card with a FAT file system (you can use the 1st partition on the microSD card)
2. Insert the microSD card and start the system
3. Go to the U-Boot console by pressing BACKSPACE on a RS232 terminal (during startup)
4. update linux

Debian Rootfilesystem

Available Rootfilesystems

Please have a look at the iMX25 Downloads section.

External Documentation

Login

Debian GNU/Linux 6.0 dhcom ttymxc1

dhcom login: root
Password: foo

Calibrating the touchscreen

# TSLIB_TSDEVICE=/dev/input/event0 ts_calibrate

Running example Qt Apps

# QWS_MOUSE_PROTO=Tslib:/dev/input/event0 /usr/qt/demos/demoname/demoname -qws
  • Remark: To start the Qt-Browser replace demoname with browser

Shutdown

# shutdown -h now

How to create a microSD-card with a rootfilesystem on it

1. Format a microSD card like following (in linux e.g. gparted, palimpsest) with Master Boot Record partition scheme

P1 FAT (Primary partition: 100MB)
P2 ext3 (Primary partition: Residual space)

2. Untar the root file system to the ext3 partition of the microSD card (Don't copy the tar archive directly to the microSD card)

Start the Console on Linux
# su
# chmod 755 /path/of/the/microSD_card
# cd /path/of/the/microSD_card
# tar xfjv path/to/RootFS/Name_of_RootFS_file.tar.bz2

Remark: If you got a *.tar.gz file so type tar xfzv ... to extract the rootfilesystem.

Busybox Rootfilesystem

Calibrating the touchscreen

TSLIB_TSDEVICE=/dev/event0 ts_calibrate

Running example Qt Apps

QWS_MOUSE_PROTO=Tslib:/dev/event0 /usr/qt/demos/demoname/demoname -qws
For the Qt-Browser change demoname to browser

Login/Shutdown system

Username: root
Password: n/a
halt


Kernel Userspace Interfaces to Access Hardware

Serial (UART) Interfaces

DHCOM (FF) UART 1 /dev/ttymxc1
DHCOM (BT) UART 2 /dev/ttymxc2
DHCOM (STD) UART 3 /dev/ttymxc4

I2C Interfaces

DHCOM I2C 1 /dev/i2c-1
DHCOM I2C 2 /dev/i2c-2

SPI Interfaces

DHCOM SPI 1 /dev/spidev1.0
DHCOM SPI 2 /dev/spidev2.0

Control the display brightness

echo <value> >/sys/devices/platform/imx-fb.0/backlight/imxfb-bl/brightness
value range: 0..255

Control GPIOs

DHCOM Name: alt. DHCOM Name: Port: Pin: SO-DIMM Pin# Linux <GPIO#>
GPIO A 2 12 154 44
GPIO B 3 21 156 85
GPIO C 2 4 162 36
GPIO D 2 5 163 37
GPIO E 2 6 164 38
GPIO F 2 7 165 39
GPIO G 2 8 167 40
GPIO H 2 9 173 41
GPIO I 3 17 175 81
CIF HSYNC GPIO J 1 10 74 10
CIF PCLK GPIO K 1 11 72 11
CIF MCLK GPIO L 1 8 70 8
CIF VSYNC GPIO M 1 9 68 9
CIF D9 GPIO N 4 21 66 117
CIF D8 GPIO O 1 7 64 7
CIF D7 GPIO P 1 6 62 6
CIF D6 GPIO Q 1 31 60 31
CIF D5 GPIO R 1 30 58 30
CIF D4 GPIO S 1 29 56 29
CIF D3 GPIO T 1 28 54 28
CIF D2 GPIO U 1 27 52 27
Export
echo <GPIO#> >/sys/class/gpio/export
Set direction
echo in >/sys/class/gpio/gpioXX/direction
echo out >/sys/class/gpio/gpioXX/direction
Set value
echo 0 >/sys/class/gpio/gpioXX/value
echo 1 >/sys/class/gpio/gpioXX/value
Get value
cat /sys/class/gpio/gpioXX/value
unexport
echo <GPIO#> >/sys/class/gpio/unexport


Initialize and test CAN

Initialize:
ip link set can0 up type can bitrate 500000
Send test message via cansend (part of can-utils):
cansend can0 100#11.2233.44556677.88
Receive message via candump (part of can-utils):
candump can0
Get can-utils:

Test display / framebuffer

fb_1Colorfill Fills the framebuffer device with a given RGB color
Syntax: fb_1Colorfill [fb (0..31)] [Display Bits (1..8)] [Red value (0..255)] [Green value (0..255)] [Blue value (0..255)]
fb_fb2BMP Copies framebuffer device data into a 24Bit BMP-File
Syntax: fb_fb2BMP [fb (0..31)] [24-Bit BMP-File]
fb_LoadBMP Loads a 24Bit BMP-file into a 32Bit framebuffer device
Syntax: fb_LoadBMP [fb (0..31)] [24-Bit BMP-File] [Display Bits (1..8)] [Transparency (0..100)]
In most common cases the "Display Bits" should be "8"


Get DH framebuffer tools:

Additional Information